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Close-recycling of industrial liquid waste
Desalination,67 (1987) 299-326 Elsevier Science Publishers B.V., Amsterdam -
CLOSE-RECYCLING
Xu Jing
-
1.
Senior
2.
Chief
I.
of
Environment
Engineering
Command,
Shanghai
Bao
Shan
Iron
Co.
demand
urban
supply water
is
used
in
oonsumption. heat waste
the
the
water
70-802
of
the
to
the
washing
transferred
pollutants
liquid
Industrial
despite
of
and
is
more
yet
About
systems
systems,
and
and
are
discharged
equivalent
to
world
the
into
the
amount
of
used.
problems
pollution In
the
Tienjin tons
wastewater
is
environment
already
scant
days
removing
of
as
or
laid
the
allowable
toxic
maximum below
Cadmium. phosphorus,
ohromium(
VI),
mercury,
below
0.05
0.0005
polychlorinated (see
0.01
ppm;
ppm;
ppm; biphenyl,
substances Fig.
1).
in
as
some
drought.
is
short
industrial
in
wasting
of
and
resulting
treatment,
severe
a large attention
part
in
specifying
arsenic,
the
effluent
following
non-detectable; below
below
methyl-mercury.
0.1
0.05
ppm; ppm;
non-detectable;
non-detectable. in
from
laws
concentrations cyanide,
was
of pollutants
anti-pollution
lead,
exist
of
China
of
souroes
non-detectable;
below
toxic
down
while
grip
resources.
usually
substances.
limits:
well
wastewater
pollutants
the
there,
water
Governments
organio
complicated
discharged
pressing
shortages,
of
the
face
in
a million
stipulating
these
water
city
wastewater.
major
and constantly
the
early
on
the
day
city’s
focused
are
example,
of
the
pollution
regions
yet
municipal
in
every
an and
oountries
water
or
take
water
many
of
countries
whioh
more
proportion
oooling
processes.
producing
Nowadays
and
in
cooling
as place,
a small
human
used
risen
taken
only
washing
water,
has has
for is
In
processes.
water
water
increase
supply
water; the
for
development
population
of
Institute
General The
of
Shanghai
Sciences
Steel
and
To
WASTE
Engineer Engineer,
Consultant.
and
LIQUID
uen
Protection 3.
OF INDUSTRIAL
299
Printed in The Netherlands
wastewater
The
states are
fairly
In
300
complex ion state:
water soluble State
cPJPb(OR)*]+, [HgS$; EDTA-Pb salt etc.
HgClz . R-M-R h+e muddy diffusion states solid state,
state:
metal qowder,oxides.carbonate. hydroxide, Pb.Cd-metal soap,PbS04, sulfide.chromateo Lcokoidal state: colloid metal,
1non-soluble in Water state
sulfide.hydroxibe. .enitiisioe State: oiWsubstance. emuiaion of organic phosphrous compound, organic metal. metal soappb-metal soap organic metal compound -oil state organic phosphorus.
Fig. 1. States of toxic substancs in waste II.
water
Treatment methodology Liquid waste can generally be divided into three
categories: organic, inorganic Pollutants
in
substances, of
wastewater
colloids,
these.
The
which
wastewater treatment The or
usually to
solids
be
cannot agent
be
biological
and
wastewater processes.
treat
wastewater
pollutants
suspended
substances,
colloids
methods
can
be
the
size
depending
on
from
wastewater
specific
substances,
particles is
Organic
applied
by
gravity,
or
of
to the
suspended
particles,
sedimentation by
or
filtration
through
membranes.
Colloidal fine
removed using
mesh
combinations
difficult. both
two.
very
inorganic to
are
various are
physicochemioal
used
they
separation
flotation. fine
whether
(l-100pml: can
only
the
suspended
matter.
Physical they
involves are
or
involves while
of
as
treatment
mainly
methods
soluble
pollutants
processes.
following
according
matter
of
makes
treatment
physicochemical
a mixture
classified
soluble
components
sophisticated,
and
are
with
easily generally
the
mostly same
collected added
or so
from
lnm
electric sedimented,
that
the
to
charge. fine
lpm, and
are
very
as
they
a flocculation particles
form
301
suspended solids. After that, sedimentation or filtration devices can be used, or reverse osmosis filtration by semi-permeable membrane can be carried out. Soluble substances
(
particles in the ion state, and cannot be removed by general methods such as filtration or settling unless these are preceded by bioflocculation form non-soluble flocculates
or special chemical reactions to (heavy metals). Other methods
such as adsorption, ion exchange, electrodialysis distillation
and
are also used to separate soluble substanoes
from wastewater. At present wastewater
treatment involves three main
processesr namely primary, secondary and tertiary treatment. Primary treatment will remove grits and suspended solids of coarse granules from wastewater by screening, sand filtering and settling, etc. Secondary treatment removes fine suspended solids first. and then soluble components; after secondary treatment the outflow will generally meet effluent standards. Organic wastewater
is treated biologically by means of the
activated sludge process, and inorganic wastewater by neutralization
flocculation,
physicochemical
oxidation-reduction
and
processes. In the event that after secondary
treatment the different component concentrations
are still
higher than the limits set for industrial use, then tertiary treatment should be employed to avoid any environmental pollution and ensure the water is fit for recycling (see Fig. 2). After secondary treatment of municipal wastewater by a biochemical
process. various kinds of tertiary treatment can
be employed; some results of applying this treatment are shown in Table 1. From Table 1 it can be observed that only the turbidity of treated wastewater by flocculation-
is improved signifioantly
settling and sand filtering. Adsorption
treatment with activated carbon greatly lowers the chemical oxygen demand (COD) and biochemical
oxygen demand (BOD)
indexes, and the majority of soluble substances would be eliminated after eleotrodialysis
and reverse osmosis
treatment. In those closed water systems where eutrophication
occurs.
the main objective of treatment is to eliminate phosphorus
I
gavity
I
I
flotation
ressure flotation
-4
fig. 2
-omFion
S
methane fuhmentatiom
for waste weter
incineration
sludge treatment
I
activated sludge trllckling filter disc
Three grades treatment
eletrolytiC
oxidation wet method
air
centrifugal filtration
vaccum fil*ration
pressure filtration
treatment neutre1izetion
inorganic fbcculatinn high polymar agents
[~~
treatment
treatment ______
secondary
primarytreetmm
__-._.._-___
I
_
a-
cond&tivity
NH4-N
1
73.6
4.5
74
4.3
570
74
4.2
12
1.0
Tab.?. comparison of water quality
!
9
‘.3
6.4
o
17.3 1, 18?_
0
7.3
19557 1 -
0.005.
1
I
8.3
0.5
(mm>
J
I
f
304 and
nitrogen.
To
eliminate
floOCUlatiOn-settling electrodialysls III.
The
result
and
origins
Close
of
reuse
in
are
discharge of
wastewater recover
as
the
of
the
production
raw
material
either
in
of
material
raw
the
wastewater
same
production.
If
industry
would
above
not
offers
minimum
consumption
water,
it
promises
profits.
anti-pollution of
The
an
and
importance
of
in
the
reused
any
in
were
applied,
effluent
waste not
materials,
energy lower
component and
an
advanced
and industrial
productivity,
many
recovery
chemical
be
technology,
development
treatment; process
wastewater
important
production
researoh
IV.
is
and
by
production,
methods
raw
maximum
to
wastewater
After
industrial
the
desirable
physical. can
produce
of
reduces
production
during
and for
eliminates
Is
elsewhere.
it
use
developed.
from
the
a
production
system
technology in
mentioned of
It
It
as
in
wastewater
other
possible
water that
about
been one
the
further
so
So close-recycling
greater
or
basically
also
of
significant.
material
of
line. as
reused
undergo
the
and
cooling
treatment
has
control
regeneration be
factory
and
should
biochemical
all.
and then
raw
production:
from
can
came
now a complete
the
wastewater
recovery
effect
very
innovations
production in
much
material
The
also
water and
until
industrial
domestic
is
flow-charts,
etc., phases
during
amount
osmosis
industrial
industrial
two
employed.
changes
methods,
There
means
of
technical
production
the
Is
close-recycling
technological
installations, water
reverse
recycling
of
phosphorus,
process
at
only and costs
and
of important
field
countries.
close-recycling-treatment
of
industrial
wastewater From
an ecological
population in
river
of
the
and water
water
equilibrium
perspective
its
density
way
beyond
and over
resulting
problems.
necessary
to
this
has areas,
eliminate
traces
of
should
therefore
organic
have the
vast To
led
to
natural
led
to
in
the
pollutants
urban building
assimilation in
ecological
being
one
eoologlcal
equilibrium,
phosphorus. and
tertiary
a breakdown
nitrogen, germs.
before
of
the
it
coloring
Municipal
treatment
up
capacity
eutrophication
restore
substances undergo
increases
is
agents,
wastewater reuse.
305 In
cases of a shortage o? freshwater
The development industrial municipal
when
discharge
of of
taken
to
have a situation resource
water
wastewater
increase
the
already
one
of
supply
look
to
can
fresh
(flash to
be
all
In
on
the
which
water.
an answer
only by
at
measures
in
demands
polluted
desalination as
Increase
Recycling. the
of
etc.)
the
strenuous which
is
upstream. is
and made
supplies,
electrodialysis,
fresh
industry
the
treatment.
countries and
urban
consumption
water
aggravated levels
of
water
three can
be
fact.,
many
distillation the
shortage
of
water.
With a view to tightening effluent controls As current waste can
be
avoided
wastewater heavy
by
has
effluent
therefore heavy
such
encourage Strict cases
water
with
which
heavy
other
wastewater
treated.
It
to
should
containing
chromium,
metals
actually
containing
wastewater
cadmium.
recover
they
of
waste,
being
discharge
etc..
from
so
as
wastewater
reuse. of
uastewater
technology and
(especially
would
economically
ensure
that
attractive.
neutralization,
heavy
conditions
causing why
discharge
was
of seepage from solid waste
certain
solids, popular
attention. organic
has
The and
are
may be
secondary
close-recycling
pollutants
metals)
there
hazardous
treating
V.
of
of
levels,
wastewater
of
cyanide.
to
flocculation
wastewater
Fig.
diluted
instead
as
control
After
reason
been
levels
quantities
amount cases,
with
discharge
greater
some
to
deal
total
an economic perspective
close-recycling
under
simply
companies
Prom
In
In
forbidden
metals
only
the
a given
standards
be
force
not
discharging with
pollution.
metals
meet
and
controls and
along
increases
to
effluent
concentration
been
some
but
seepage
from
these
pollution.
That
is
attracting
more
and
close-recycling
inorganic
in
solidified,
technology
wastewater
Is
one more
for
presented
in
3. Individual The
techniques
close-recycling
combination
of
many
of system
individual
the
close-recycling
of
wastewater
techniques.
process treatment Some
of
is these
a
306
It
I
307 teohnfques of
and
wastewater
1.
their
techniques
colloidal
particles
molecular
pattern
flocculation
of
since
repel
one
another
to
When
charge
(usually
of
they
have
some
all
colloida
counterthrust
force
of
takes
additives
are which of
salt
molecular
charge
I giving
Moreover.
it
with
minimum
consumption
efficient.
In
wastewater
this
is
needed
and
agent deuatering
of
of
pretreatment
with
i).
The
properties
are
shown
polymers produce
are high
rare,
molecular
of
or
a high
recommended, the
as
improved
settling
weight
is
high
links,
at
the
it
only the
is
also
is
a small
and
extremely amount
flocculation,
of
filtration
employed or
it
flocculation
molecular
treatment some
high
2.
Cationia
Table
acid quite
all
as
a
solid-liquid
effectiveness. of
in
metal hydrogen
molecular
complete
tertiary
metal
use
the
thus
some
colloidal are
particles
It
to
and
hydroxide)
and
treatment,
amazing
polymethylacrylic
of
colloida.
agents
size
colloidal
to
during
separation
The during
its
due
charge
(ferric
strongly
group
electric neutralize
the
those
is
because
a large
to
increases
force granule
opposite
added
produce
they
remains
hydrolysis
salt
agent adhesive
velocity.
to
through
in
charge,
flocculation.
hydroxide).
a large
the
2);
water
Because
particles
electric
Fig.
the
a aoattering
cm).
pattern,
achieve
ferric
(aluminum
a strong
reacts
To
have
pattern of
by but
chemical
surface
are
surface
in
flocculation
produces
here.
separated
10-4
particles
(See
soluble
-
scattering
place.
positive
ions
the
the
especially
aluminum
process
the
necessary
are
applicable,
treatment
desorlbed
flotation,
colloidal
charge)
among
oxides
in
10D7
a negative
or
force
by
scattering
a positive charge
or
1 nm which
these
their
electric
flocculation
the
are
nm are
separated
movement
gravitational
salts
than be
range
and
10
sedimentation
leas
have
Brownian and
stable.
for
metals
than
of
(flocculation
water
the
heavy
particles~blgger
traditional
the
applications
contains
by flocculation
Separation
Suspended
of
combined
whioh
and
amino
but polymers
the
molecular ester;
include
anionic
acrylamide should
flocculation
polymers
be
and
group mentioned.
non-ionic
which
can
By the
I pClyaCwlat2
CiFG&-CT~Z& --
9-1,
"above6
f---
ferric sulfLte ferrous chloride ferrous ~~_.__ gulphate.
agents
I G2P dose of jiCn -^, be avoid in abs r;;l;;ion sho*Jld 5 . I
if treatment Condition is not fa %r:~r?blc residue :'eand chromarid
I soae msin agent f,rnctionis avai-lable oolyvinyl lmine Ez cation aPPlicabi:chennegative electric charge is z 5. tfle Coa-polyvinyl pyridinetO acidic applied singly. !poly 8 g &an_ts. _ thiourea saries non-extrnon-ion e" type coa- poly acrylamide emes of acidic or -gulants ; alkaline
I
$ F vl type CCa 3 g gulants
anion
:. 5 ferro k" 2 r( -salt
1
categories
* 4 z
categoies and functLon of coagulant9
for I remarks coagulation J aluminum sulfate geneaally apolied'-jointly wiyh fe ___~. lumlnium 6-B rr0 sals to boost efficent of coa - __._r.. sodium QAation effective deckromation n .*.aluminate ~salt change in PH value of solution. alumi~um~.chlorJd~
Tab.2
309
side
link
cation
there
and
particles The
of
cost
is
of
raw
is
recover
acid
agent
from
the
silicon.
In
efficiency
be
to
complexity
of
its
easily adsorb
the them.
in
to
production
of
to
flocculation kinds
get
a high
and
and and
municipal
containing
poly-ion
and
charge high
because and
polynuclear
the
agents the
pA value
and
agents
can
compounds
particles
flocculation to
oxides. of
complex
suspended
molecular according
metals
hydrogen
flocculation
of
increase
flocculation
temperature
electric
the
also
heavy
by
molecular
Inorganic
flocculation
eliminate
wastewater
components,
to
molecular
sedimented
high
of
acid
we can
high
high
technology
molecular
sediment
and
by
density
sulfuric
a high
adding
agents.
inorganic
sedimented
recovery
wastewater
doses
of
treatment
by
while
varying
the
waste
applying
character.
produce
neutralize
fine
treatment.
quickly
to
neutralization
treat
changeable
added
by
inorganic
applied
anion,
flocculate
wastewater
membrane
flocculated
both
be
metallurgical
agents
can
Usually
its
used
significantly
flocculation
produce
in
many
can
pretreatment the
can
molecular
agents
silicon.
in
which
high
which
We have
oontaining
in
contains
flocculation
flocculants.
which effectively
low.
of
substances
molecular
used
also
wastewater
organic
to
substances
material
Application
Industrial
are
polymers
suspended
polyacrylamide ii).
a CONA2 group
non-ion
agents
nature
of
to
and can
be
the
wastewater. 2.
Exchange
Ion based
and
exchange on
the
hinge
and group
developments
in
involving special metals been
a kind hinge
to
serves resin
obtain the
chelating and dramatic
of
resins
oxidation-
of
of
have of
in
can
opened
the
into
Aere
the
the
exchanger.
Recent
up new horizons, acid
with
group hot
selectively
resins.
and
introduced
ion
weak
regeneration which
is
polymer
styrene
shape.
function
reduction
developments
molecular
group
resins
capable
high
a ball
research
double-function group
of
structure
a functional
moleoules
functional
alkaline
is
co-polymer
divinylbenzene, high
adsorption
resin
adsorb
Recently,
manufacture
and
weak
water,
of
there large
heavy have mesh,
310 multi-pore
resins
Colloidal balls (about
l-10 and
narrow
ion
affects
the
expand would
However,
as
pore
while
it
is
fine
surface
area
200-1400~.
for
be
rather is
(10 There
high
molecular
weight
adsorb
a high
and
desorb to
the
development
resin,
the
of
is
large of
following
expand
that
the
mesh,
more
and
it
has
in
resin
the
As
has
and It
resin
it
is Following
and resin
chelating in
containing
significant.
can
favorable so
by
the
heavy
The
proaess
has
applications:
a.
Condensation
b.
Elimination
and
recovery
of
high
of
low
of
metals
conaentrations
and of
reuse
impurities
of
water. in
wastewater. c. in
Elimination
wastewater d. e.
discharged
Treatment
fluctuations Seleotion
selectivity.
the
of
resin,
wastewater.
multi-pore
with
ions
adsorption.
and
wastewater
very
70.0005i).
aontraction,
organic
opaque
of of
organic and
of
a large
super-porous
expand
more
Large
groups
exchange-adsorption of
resin,
form
by
(average
and of
strength.
in
distribution
of
would
only
application. in
substances
treatment becoming
to
exchange
expansion
swell
ions
pore
easily of
treatment
function
close-recycling metals
can
resin strength
mechanical
in
hinge
greatly
mechaniaal
constituted,
colloidal of
applicable
hinge
formed
kind
freely
velocity
characteristics the
be
and
low
of
so
fine
another
can
is
and
239000-2301000P
structure
resin
would
the
of
loss
being
of
pore
its
limited
is
interstices
the
0.1
through
Modification
manufactured
particles, m2/g)
remain (below
place
resin
large
interstices
fine
there
and hinge
hard
non-consecutive
fine,
takes of
water
transparent
spaces area
usually
high
resin
fine
resin.
structure. of
surface
significant
would
its
small the
layers
very
structure in
multi-pore
balls,
the
in
without
a resin
that
characteristics;
reduced and
a co-polymer
adsorption
spaces
fine
of
numerous
a very
significantly be
mesh,
so
exchange
its
slightly such
with
fine
influences
basis of
together 11,
and
the
consists
squeezed
m2/g)
on
resin
of In
in
industrial
volume and
concentrations
and
separation
large
of
toxic
wastewater
subject
conoentration. of
substances
volumes.
metals
by
resin
to
large
311 Tab.3
Categories and characteristics of membrane and separation techniques membrane csteg3ries
electro-
dynznic function
characteristics
ion exchange
dialysis
membrane
ciiflusionperneation
permeation membrane
fine bltra;ioc
fine holl3:0.ess poly.:?r
membrane hollxnes
I,
of memxalk
ultra-filter l~~~f~~er 1
breDared
acraordarvI
o the siae moleular of-solution
V;aterselective psrma-dater permeation tian meTCrane DressuEeh d concentration dJff:er,ce 20-1C?%~/cm' f solution
1 chromium
regeneration agent NaOH
rinse water
neutralization sedimentation treated
( desalted fig.4
water water)
I I
312 f.
Elimination
of
3.
Hembrane
separation
Pending through the
permeation
a high
membrane
helps
to
separate
so In
substance
dynamic
change
of
easily Please
refer
is
as
the
in
to
Resin
in
high substances
and
pH.
The
production.
characteristics
of
esobange ions
various
aots
as
upon
the
the
is
size
resin
demonstrates
electric
oharge
while the
H+ and
those
ion
exchange
following
the
three
dynamic
resin
a high
molecules).
and
If
mind:
of
force
exchange
molecular
a molecular
water
easily, to
in
on
take
ooncentration the
is
through
introduced will
place.
osmosis,
membrane
of
By utilizing membrane
in
borne
are
osmosis
take
difference
depends for
solution
will be
permeate
permeate
of
difference
should
whioh
(easier
membrane
of of
temperature
diffusion
diffusion
exchange
permeation Ion
the
concentration
struotare
permeability;
treatment
separation
in
no
continuous
directly
the
separation
points
solution
radius
advantages:
the the
reused
3 for
of
applied
The
be
membrane,
and
fundamental
repelled.
of
or
techniques.
a result
is
for for
conaentrations of
permeability,
anionic
make kind
oamoaia
side
c.
to some
difference
following
fluotuation
Table
different
either
b.
of
to
membrane
we need
consumption;
and
can
to
the
suitable
by
separation
Diffusion
of
it
solution
membrane
hinge
components
pressure
membrane,
the
membrane
called
concentration
energy
solutions
influenced
a.
is
of
percolation
the
of
and
kind
technique
has
low
and
condensed
the
this
obtain
molecules
selectivity
concentration
through
separation
concentration
resin
solvent
the
the
difference,
phase;
operation;
place
and
difference).
Membrane
If
to
pass
wastewater.
utilize
this
(potential
pressure
solution
change
order
in
membrane,
we can
substances;
separation.
metals
techniques
of
molecular
solution,
the
organic
polymer
sieve: the
the
hydrophilic
seleotive like
enormous
diffusion
cationic
membrane
of
velocity ion
ionio
opposite of
for
membrane.
to
that
charge
of
coefficient to
Otl-,
the
are of acid
313
HNO,
radioactive waste water tank
NaOH
oh 10 edimentation * filteratio
starag
effluent (1)
trea&ent,of radioactive waste water with ion excange resin
primary purified water 990m30. 002-o. radioactive waste water 100!Z5 O.C2-0.25%
003%
lC-6micro-curie/ml
eletrodialysis primary purifie; solution secondary water 3 100~1~0.02-0.3X ;.‘2”-“o 3is lo-'micro-curie/ml 10-4mic;b_ curie/ml electfodialysis
c 'c 04 $:a
g&i% 1 ar g
?JZ IQ%
.&"E "G
treated water *9
80m' 0.0001% 10-8$licrOJ curuie/mL
l-4 namted wasteLiquid 1.2-1i'4% LO-2-LO-4microcurie/ml
,Oml 1.52.7% 10-3micro-cu.rie/mL ? / evapor&bi.on
(2) treatment of riadioactive waste water with membrane
fig.?. treatment of radioactive waste water with ion exchange resin and membrane
314 and alkali can be separated from other substances. This process is employed in olosa-recyoling
to recover acid and
alkali without consumption of eleotricity and it is very promising in application. The principle is as follows: If the concentration of the solution is greater on one side of the membrane and the size of the molecules smaller. molecules with an electric charge opposite to that of the membrane permeate through more easily. Greater physicoohemical
stability and a thinner
membrane make diffusion easier. The membrane is more efficient if the permeation pressure on the moving water is low and there is a favorable selective diffusion coefficient of the solvent molecules
(i.e. a high transport velocity and
segregation speed). Applications of diffusion-permeation a. To separate NiSO,, (CuSO,,) and recover APSO,, in metallurgical
works using the wet method.
b. To separate A12(S04) and recover P12S04 from aluminum oxide processing effluent. c. To recover chromium from electroplating d. To recover hydrofluoric
effluent.
acid and fluorosilicic
acid
from titanium and lead effluent. e. To recover hydrochloric acid from extraction or pickling liquid. f. To recover sulfuric acid from iron and steel pickling effluent. g. To recover sulfuric acid from gluaose processing liquid. In recent years. exchange-adsorption
and membrane
separation techniques have been recommended for the treatment of (a) electroplating
effluent containing chromium using ion
exchange resin (see Fig. 41; (b) radioaative liquid waste using ion exchange resin and membrane
(see Fig. 51; (c) iron
and steel work wastewater with ion exchange membrane
(see
Fig. 6); (dl Pb-wastewater with ion exchange resin and chemical process (see Fig. 71; (el cynamide wastewater with electrodialysis
process (see Fig. 8); (f) paper mill black
liquid by electrodialysis
(see Fig. 9); and (g) resin
regeneration wastewater by ion exchange resin (see Fig. 101.
315
4'residue liquid H2S04
a)g/l ti_+4+FeSO4 -Hi
FeSO4 12Og/i
&H+
I-Fe++-+ wai:er
I +
3
I
*H2S04+.
l-H2S04
c.EL2sop
l*2so4
( I' 2 %7 o+ ' 22: 16og/l 2 1 4. 2Wl 5 H2S04 ZOO-22Og/l 2 'B FeS04 180-2OOg/l
__ -+ "4 o I electrolytic
t. *cathode reac;on anode reaction y20f'H++OHH2S04~2H++S0;- ZH++SO-=-H SO 4-2 4 40H-r=0;+2H20+2 coagulant5 a-settling tank
suJp.huricacid reolenisbmut _.1 7 pickiing tank H2S04 3OOg/l FeS04 2Og/l
Fig.6. Close-recycle treatment of waste acid from iron and.steel work
_
organic Pb-waste M%fPP
-1
Fi.g.7.
Fe2(S04)3~1 roat
NaOH HCl
316
Fig.8. electrodailyaistreatment for cyamide waste water (closed system)
Cl
pH 4-6 -
b'g.9.Recovery of alkali from Paper 1~11 black liquid
317
cation exchange anion exchange resn regenerat- resin regeneration agent ion agent acid waste water (NCI+NaCI)
alkaline I waste water.I
l
'neutralization" R=N ~ discharge R=NHCI pH7.O+O low l~.~l volume weak alkali
I ~I R-COOH I SI
(NaOH+NaCl)I l weak acid lo ~i~I i.C E R
fig. i0. treatment of waste liquid from resin regeneration
--coagulant
waste water
I
*~ o
I
~a-i
Hsand
secondly treat~entF--1 c a g u ~ on
~filtrationJ I
NaOCI ]_I25U drum filtration
I HCI desalted wa~er (for reuse)
Fig.1 D m
'4
318 Tab.4.
eater 7il,zlity after electr~:~x!;al)rsi5 trc2tment
Tab.5.
Water quality
of permeated industrial water
(Pnm!
water
and
! Fe
319 4. Resin regeneration
in the treatment of wasteuater
Resin has been widely used in the production of pure water, but it has to be regenerated with acid and alkali (see Fig. 6). During the regeneration process and before discharge, wastewater neutralization
should be neutralized.
In the
process it is hard to handle pollutant
sediments without causing
environmental
some
pollution. In
order to avoid secondary polution. it is advisable to use weakly acidic resin in the treatment of neutralization effluent as it does not give any sediment in the discharge. VI. Examples of close-recycling 1. Desalination
and reuse of municipal wastewater
As municipal water supplies tend to be very tight, municipal wastewater has to be treated and reused; close-recycling
consisting of biochemical
by flocculation
and electrodialysis
treatment followed
is suitable for this
purpose, and can prevent much squandering of fresh water. In Tokyo, experimental
treatment of this kind was carried out on
over 250 m3/day of wastewater Wastewater
at the Southsand Street
Treatment Plant. the treatment capacity being
later increased (see Fig. 71. Pretreatment,
especially by 25 urn drum filtration,
eliminates microbic and ferric hydroxide pollutants and so avoids the membrane becoming clogged up, while at the same time sodium chlorate is added, and although some residue of ahlorine (about 0.5 ppm) would appear. it would not affect the membrane. Usually large pore polypropylene membrane is used and recycling with pH l-2 Cl every 30 minutes is necessary. This method is suitable for the secondary treatment of wastewater
containing 1000 ppm TDS or for the
treatment of industrial wastewater
containing 2000-4000 ppm
of TDS. In Japan this method was applied to relieve a shortage of about 900 million m3 of fresh water in the Kant0 District. 2. Vasterrater rrom chemical works Generally the wastewater
from chemical works contains
about 700-2000 ppm TDS and not a lot of organic or inorganic
320
---I
321
Tab.6. Result of ferrite treatment of Lavy metals
purifying tank
collection
industirial vater
I ultrafiltration
I
I
+
I
1-1
ion exchange
b-Iactive I
1
I
,
carbon/ 1
fig.12.
Tab.7.
result of ultra-filtration membrane treatment of eletronh3r~'ic coating material source liquid
pH
A.5
8.72
8.75
solid -_Tatter (%)___~-10 -_ amine(nor3al) conductivity $J/cm)
uf;tra-filtration reverse osmosis treated water tieated liquid
q-9 89.8
83.5
1690
2100 -
__.
..__..-!L?!.57.1 1440
322 substances
are
combination
present
of
techniques
is
organic
fresh
be
and
by fine
can
reverse
osmosis,
eliminated
be
rate
by
and
172,
membrane
after
organic
acid
3.
Wastewater
Large
so
the
(see
fror
volumes
of
from
from
processes
are
industries.
In
machinery jointly
applied
Central
Research
alkaline
containing eliminate to
water
and for
heavy
metals,
the reuse.
The
(see
Fig.
suspended water
11).
is
solids.
yeSO
is
the
added NaOB is
and
part
filtered pR value reverse micro-ohm
mixed to
with adjust
and
is
for
the sand
and
reuse of
are at
the
acidic
to of
and
is
applied is
to prior
a
by-product
process, to
and cm.
produce wastewater
electrodialysis Fe-0 acidic
and
eliminate
adjusted.
the
wastewater
neutralization,
the
wastewater
industries
electrodialysis
process
per
the
by
electrical
combined
osmosis
of and
metals,
alkaline
by
of
drop
regenerated
treatment
by
will
iron
heavy the
for
be
compounds
machinery
process
except
first
0.1
added
Fe-0
can divalent.
5).
water
are
technical
is
pollutants
treatment
the
overall
the
The
be
By
of
membrane
of
followed
by
being
the
metals,
the
generated
conductivity metals,
In
of
In
technique,
wastewater
Fe-O
exchange
year
the
and in
techniques
reuse.
heavy
close-recycling alkaline
ion
water
nitrogen
and
acidic
In
the
and
can
l/2.
salts 99% of
containing
treatment
by
one
4 and
Japan,
COD (Hn)
calcium,
generated
Institute.
osmosis pure
19%.
membrane
and
the
wastewater,
reverse extra
by
silicate,
electrical
boilers,
in
by
Tables
the
solids sand
and
After
to
by
solution
silicate
eliminate
suspended
filtration
ions.
wastewater
wastewater daily
total
years of
rinsings
by
elimination
mainly
substances,
oxalic
the
91% of
three
consist
and
eliminated.
of
to
possible
By flocculation, 2/3,
of
be
is
sedimentation,
monovalent
ions).
the
operation.
by
osmosis
possible
of
a
reverse
entirely
961
flocculation,
of
can
not
It
than
filtration.
NE4-N)
is
use
More
95-971
multivalent
it
Industrial
reduced
(95-961
(N03-N.
as
using and
eleotrodialysis.
for
eliminated
filtering
Close-recycling filtration
methods.
content
and
by
water
physicochemical aan
it.
recommended,
substances
obtain
in
flocculation,
and ion In
extra
the
seoonh
containing
pE value
pure
exchange.
to
its part,
heavy 10.
the
323
1
. watei resin coating matelrial
extra-filtration
/ reverse
1
1
osmosis
fig. 13.
F-on
electro-
plating tank
1
vacua condensatio cooling water
1
condensed liquid
sludge
9
chromium eletro?latin tank
cwles6er3
NiSO4
r-=
fig. 14.
recovery
/L
regematian
ion exchange
I
concentratedNISO,
I
Fig. 15.
324
temperature generate
Is
separation 6.
are
ferrite wave
out,
in
can
with
the
be
blown
can
used
in
to
solid-lfquid
shown
reduce be
in
and
results
to
produotlon
also
is
in
salt
carried
magnetia
Table
content out
body
to
and
or
the
electric
Yastewater from the automobile Industry
In the systems,
automobile where
separately. water the
motor
can
teohniques. tons
of
It
teohnologiaal in
suspended
solids of
eliminate part there
is
paints and
the
can
be
ratio
per
to
meet
12. in
is
5.
the
13).
aontains
is
the
suspended
and
13-331
Wastemater amount industry
organic are
the
in
the
of
heavy
metals
its
the
was
discharged
It
part
in (3)
treatment
its
which
it
BOD is solids,
pg
value
The
results
7,
which
ooating
soluble
is
its 6-9.
and
of shows
material
that
are
solids.
industry
industry contains. after
to
3;
electrophoretlc
Table
eleotroplatlng it
to
after
color,
from the eleetroplatlmg
from
used
coating;
non-volatile
in
total
is 30 in
osmosis
substances.
solids of
from
of a high
membrane
Ohm,
given
is
a lot with
example,
10s
The
eleotrophoretic
milky
1.000-2r000
recovery
are
totally;
reverse of
hundred
12,000-14,000
flotation
reused
For
two
treatment
BOD drops
from
a liquid
numerous
Wastewater the
Fig. it
only
ultrafiltration by
is
be
In
close-reoyoling
wastewater upward
as and
thousand
requirements.
there
and water
by
(see
(1)
domestio
treated
mg/l,
eliminated
part
can
is
wastewater
pressure
rinsing
recovered
and
of
the
this
substances,
resistance
99.82
In
High
material
treatment
day
for
mainly
contains
of
water
water
4.000-6.000
help
replenish
cooling
reused
the
reused
painting
fifty
consumption
two
treated
ultrafiltration.
to
Fig.
water
coating
With
is
and
manufactures
water
by
are
wastewater
after
Co.
oonoeyed
recycled,
necessary
BOD.
are
reused
and
day.
is
is
wastewater
is
micro
(2)
be
process
presented
water
Automobile
per
fresh
content
also
daily,
tons
wastewater industrial domestic
oooling
Nissan
vehicles
thousand
and
treatment,
water,
rinsing Japan,
Industry,
domestic
After
industrial
of
air
separation
absorption.
4.
for
‘,C,
magnet
electrodialysis
reuse
residue
60-70
then
carried by
ppm for
to
and
Desalination
(500
it
raised
ferrite,
is In
only
the
notorious early
neutralization
days
325 which
treatment, the
ion
caused
exchange
rinsing
water
has
been
reuse.
and
liquid
regeneration
undergoes
electrodialysis
or
interim
reverse
process
all
salts;
these
technological
wastewater
at
the
rinsing
wastewater
at
the
shifting
involve
a combination
diffusion
membrane
Recovery In Cr3+
the and
which
of Fe*+
membrane
while
Fe,
hydroxide the
will
also is
of
Reusing In
The
the
concentration
the
methods
generally
reverse vacuum
osmosis,
evaporation
and
be
high
concentration, to
the the
the
chromate
in by
anode
the
into
electroplating
tank
cathode,
and
Cr
Part 6+
vacuum
for
the
by
for
anode
chamber, react
tank
electroplating
in
will
eliminated.
the
isolated
cathode
solution
after
between
for
the
of
solution,
(cations) to
oxidized
rinsing
the
chamber
by
and
a residue
recycling
impurities
produced
to
chromium
liquid
membrane
generated will
is
concentration
concentration
process.
chromate
back
to
recover
whole
treatment. low
high
waste
the
the
ions
be
conveyed conveyed
and the
Recovery
replaced
and
Cu in
solution
conveyed water
Zn.
involves
accumulates
through
radical
compound in
tank
pass
close-recycling
electrodialysis.
regularly
electrolysis.
chamber
covering
electroplating
gradually
electroplating
crystallize
the
chromium from
be
to
exchange.
of
electrolysis.
chromium
should
treatment
membrane
a distillation-
at
and
Now
by
before
stage.
ion
the
from
mainly stage
of
permeation,
isolated
aimed
with
wastewater
in
waste
concentration
applied
are
pollution.
adopted
osmosis,
is
steps
process
Electroplating
environmental
process for
concentration
severe
of the
with
hydroxide 3+ Cr
the
anode
reuse.
and
Rinsing
concentration,
tank,
and
cooling
reuse
(see
Fig.
is water 14).
liquid electroplating condensed
by
process, vacuum
liquid
evaporation
of
low
or
I
1 H2S04 FeS04
the
Pig.16.
326
eleotrodialysis.
and
electroplating liquid)
is
reused
after
is
regenerated
to
ion by
condensed
while
conveyed
be
process,
the
tank
the
acid during
regeneration.
after
vacuum
evaporation
(or
tank.
the
See
desired)
flowchart
in
water
Fig.
salt
in
the
the
solution,
osmosis
to
oan resin
permeation
salt
reverse
conveyed
the
exchange
nickel
Nickel
after
is
Rinsing Cation
from
to
concentration
By a diffusion
solution
is
tank.
separated
waste
concentration
conveyed
(low
treatment. acid.
is
is
water
recovery
exchange sulfuric
sulfuric
liquid
cooling
if
a high
electroplating
15.
Acid reooverp tror an acid rinsing tank In falls
the
acid
due
to
solution.
The
separate
free
sulfate
is
membrane ions on
the
permeation
acid
ferrous to
on the
side
Fig.
method ion
(pure side,
and
gradually metals
can
be
in
used
solution.
cathode
membrane
(see
other
sulfate
metal the
efficiency and
Fe
Ferrous
iron)
by
isolated
sulfuric
sulfuric
the
to
radical
acid
is
collected
161.
Conolusion
they
close-recycling been
only
control
i.e.
technological
basis
manufacturing the
(closed)
ion
all
objectives
of are
membrane
of
greater realized.
the
made
easy. not
have
process),
relationship over
in
the
soda
(using sulfide),
soda
produotion
non-aqueous
electroplating
processes
etc. efforts in
to
Innovations all
sodium
grade
non-aqueous
close-recycling fully
and
manufacturing
(high
eleotroplating)t still
problems
as
technical
control. be
that
olose-recycling
instead
mercury
systems,
make
wastewater
into
paper alkali
exchange
static
to
only
though point
all task,
other
wastes”
research
without
dyeing
(ionizing us
and
many
analysis,
“three
pollution-free dioxide
been
organization,
continue
of
not
sophisticated
also
benefit and
processes
technology: chlorine
but
have
and
a technological
really
a very
above
treatment
from
has is
cost
recommended
wastewater
technical
production the
in
difficult
techniques
administration,
using
very
control
considered,
on
use
application
wastes”
world
to
seem
their
between
techniques
put
may not view,
“Three
Let
from
through
recently
be
acidic of
diffusion
transferred
anode
The
of
process
accumulation
electrolysis
pass
VII.
rinsing the
the
to
ensure
treatment
that of
the
industrial
CLOSE-RECYCLING
Xu Jing
-
1.
Senior
2.
Chief
I.
of
Environment
Engineering
Command,
Shanghai
Bao
Shan
Iron
Co.
demand
urban
supply water
is
used
in
oonsumption. heat waste
the
the
water
70-802
of
the
to
the
washing
transferred
pollutants
liquid
Industrial
despite
of
and
is
more
yet
About
systems
systems,
and
and
are
discharged
equivalent
to
world
the
into
the
amount
of
used.
problems
pollution In
the
Tienjin tons
wastewater
is
environment
already
scant
days
removing
of
as
or
laid
the
allowable
toxic
maximum below
Cadmium. phosphorus,
ohromium(
VI),
mercury,
below
0.05
0.0005
polychlorinated (see
0.01
ppm;
ppm;
ppm; biphenyl,
substances Fig.
1).
in
as
some
drought.
is
short
industrial
in
wasting
of
and
resulting
treatment,
severe
a large attention
part
in
specifying
arsenic,
the
effluent
following
non-detectable; below
below
methyl-mercury.
0.1
0.05
ppm; ppm;
non-detectable;
non-detectable. in
from
laws
concentrations cyanide,
was
of pollutants
anti-pollution
lead,
exist
of
China
of
souroes
non-detectable;
below
toxic
down
while
grip
resources.
usually
substances.
limits:
well
wastewater
pollutants
the
there,
water
Governments
organio
complicated
discharged
pressing
shortages,
of
the
face
in
a million
stipulating
these
water
city
wastewater.
major
and constantly
the
early
on
the
day
city’s
focused
are
example,
of
the
pollution
regions
yet
municipal
in
every
an and
oountries
water
or
take
water
many
of
countries
whioh
more
proportion
oooling
processes.
producing
Nowadays
and
in
cooling
as place,
a small
human
used
risen
taken
only
washing
water,
has has
for is
In
processes.
water
water
increase
supply
water; the
for
development
population
of
Institute
General The
of
Shanghai
Sciences
Steel
and
To
WASTE
Engineer Engineer,
Consultant.
and
LIQUID
uen
Protection 3.
OF INDUSTRIAL
299
Printed in The Netherlands
wastewater
The
states are
fairly
In
300
complex ion state:
water soluble State
cPJPb(OR)*]+, [HgS$; EDTA-Pb salt etc.
HgClz . R-M-R h+e muddy diffusion states solid state,
state:
metal qowder,oxides.carbonate. hydroxide, Pb.Cd-metal soap,PbS04, sulfide.chromateo Lcokoidal state: colloid metal,
1non-soluble in Water state
sulfide.hydroxibe. .enitiisioe State: oiWsubstance. emuiaion of organic phosphrous compound, organic metal. metal soappb-metal soap organic metal compound -oil state organic phosphorus.
Fig. 1. States of toxic substancs in waste II.
water
Treatment methodology Liquid waste can generally be divided into three
categories: organic, inorganic Pollutants
in
substances, of
wastewater
colloids,
these.
The
which
wastewater treatment The or
usually to
solids
be
cannot agent
be
biological
and
wastewater processes.
treat
wastewater
pollutants
suspended
substances,
colloids
methods
can
be
the
size
depending
on
from
wastewater
specific
substances,
particles is
Organic
applied
by
gravity,
or
of
to the
suspended
particles,
sedimentation by
or
filtration
through
membranes.
Colloidal fine
removed using
mesh
combinations
difficult. both
two.
very
inorganic to
are
various are
physicochemioal
used
they
separation
flotation. fine
whether
(l-100pml: can
only
the
suspended
matter.
Physical they
involves are
or
involves while
of
as
treatment
mainly
methods
soluble
pollutants
processes.
following
according
matter
of
makes
treatment
physicochemical
a mixture
classified
soluble
components
sophisticated,
and
are
with
easily generally
the
mostly same
collected added
or so
from
lnm
electric sedimented,
that
the
to
charge. fine
lpm, and
are
very
as
they
a flocculation particles
form
301
suspended solids. After that, sedimentation or filtration devices can be used, or reverse osmosis filtration by semi-permeable membrane can be carried out. Soluble substances
(
particles in the ion state, and cannot be removed by general methods such as filtration or settling unless these are preceded by bioflocculation form non-soluble flocculates
or special chemical reactions to (heavy metals). Other methods
such as adsorption, ion exchange, electrodialysis distillation
and
are also used to separate soluble substanoes
from wastewater. At present wastewater
treatment involves three main
processesr namely primary, secondary and tertiary treatment. Primary treatment will remove grits and suspended solids of coarse granules from wastewater by screening, sand filtering and settling, etc. Secondary treatment removes fine suspended solids first. and then soluble components; after secondary treatment the outflow will generally meet effluent standards. Organic wastewater
is treated biologically by means of the
activated sludge process, and inorganic wastewater by neutralization
flocculation,
physicochemical
oxidation-reduction
and
processes. In the event that after secondary
treatment the different component concentrations
are still
higher than the limits set for industrial use, then tertiary treatment should be employed to avoid any environmental pollution and ensure the water is fit for recycling (see Fig. 2). After secondary treatment of municipal wastewater by a biochemical
process. various kinds of tertiary treatment can
be employed; some results of applying this treatment are shown in Table 1. From Table 1 it can be observed that only the turbidity of treated wastewater by flocculation-
is improved signifioantly
settling and sand filtering. Adsorption
treatment with activated carbon greatly lowers the chemical oxygen demand (COD) and biochemical
oxygen demand (BOD)
indexes, and the majority of soluble substances would be eliminated after eleotrodialysis
and reverse osmosis
treatment. In those closed water systems where eutrophication
occurs.
the main objective of treatment is to eliminate phosphorus
I
gavity
I
I
flotation
ressure flotation
-4
fig. 2
-omFion
S
methane fuhmentatiom
for waste weter
incineration
sludge treatment
I
activated sludge trllckling filter disc
Three grades treatment
eletrolytiC
oxidation wet method
air
centrifugal filtration
vaccum fil*ration
pressure filtration
treatment neutre1izetion
inorganic fbcculatinn high polymar agents
[~~
treatment
treatment ______
secondary
primarytreetmm
__-._.._-___
I
_
a-
cond&tivity
NH4-N
1
73.6
4.5
74
4.3
570
74
4.2
12
1.0
Tab.?. comparison of water quality
!
9
‘.3
6.4
o
17.3 1, 18?_
0
7.3
19557 1 -
0.005.
1
I
8.3
0.5
(mm>
J
I
f
304 and
nitrogen.
To
eliminate
floOCUlatiOn-settling electrodialysls III.
The
result
and
origins
Close
of
reuse
in
are
discharge of
wastewater recover
as
the
of
the
production
raw
material
either
in
of
material
raw
the
wastewater
same
production.
If
industry
would
above
not
offers
minimum
consumption
water,
it
promises
profits.
anti-pollution of
The
an
and
importance
of
in
the
reused
any
in
were
applied,
effluent
waste not
materials,
energy lower
component and
an
advanced
and industrial
productivity,
many
recovery
chemical
be
technology,
development
treatment; process
wastewater
important
production
researoh
IV.
is
and
by
production,
methods
raw
maximum
to
wastewater
After
industrial
the
desirable
physical. can
produce
of
reduces
production
during
and for
eliminates
Is
elsewhere.
it
use
developed.
from
the
a
production
system
technology in
mentioned of
It
It
as
in
wastewater
other
possible
water that
about
been one
the
further
so
So close-recycling
greater
or
basically
also
of
significant.
material
of
line. as
reused
undergo
the
and
cooling
treatment
has
control
regeneration be
factory
and
should
biochemical
all.
and then
raw
production:
from
can
came
now a complete
the
wastewater
recovery
effect
very
innovations
production in
much
material
The
also
water and
until
industrial
domestic
is
flow-charts,
etc., phases
during
amount
osmosis
industrial
industrial
two
employed.
changes
methods,
There
means
of
technical
production
the
Is
close-recycling
technological
installations, water
reverse
recycling
of
phosphorus,
process
at
only and costs
and
of important
field
countries.
close-recycling-treatment
of
industrial
wastewater From
an ecological
population in
river
of
the
and water
water
equilibrium
perspective
its
density
way
beyond
and over
resulting
problems.
necessary
to
this
has areas,
eliminate
traces
of
should
therefore
organic
have the
vast To
led
to
natural
led
to
in
the
pollutants
urban building
assimilation in
ecological
being
one
eoologlcal
equilibrium,
phosphorus. and
tertiary
a breakdown
nitrogen, germs.
before
of
the
it
coloring
Municipal
treatment
up
capacity
eutrophication
restore
substances undergo
increases
is
agents,
wastewater reuse.
305 In
cases of a shortage o? freshwater
The development industrial municipal
when
discharge
of of
taken
to
have a situation resource
water
wastewater
increase
the
already
one
of
supply
look
to
can
fresh
(flash to
be
all
In
on
the
which
water.
an answer
only by
at
measures
in
demands
polluted
desalination as
Increase
Recycling. the
of
etc.)
the
strenuous which
is
upstream. is
and made
supplies,
electrodialysis,
fresh
industry
the
treatment.
countries and
urban
consumption
water
aggravated levels
of
water
three can
be
fact.,
many
distillation the
shortage
of
water.
With a view to tightening effluent controls As current waste can
be
avoided
wastewater heavy
by
has
effluent
therefore heavy
such
encourage Strict cases
water
with
which
heavy
other
wastewater
treated.
It
to
should
containing
chromium,
metals
actually
containing
wastewater
cadmium.
recover
they
of
waste,
being
discharge
etc..
from
so
as
wastewater
reuse. of
uastewater
technology and
(especially
would
economically
ensure
that
attractive.
neutralization,
heavy
conditions
causing why
discharge
was
of seepage from solid waste
certain
solids, popular
attention. organic
has
The and
are
may be
secondary
close-recycling
pollutants
metals)
there
hazardous
treating
V.
of
of
levels,
wastewater
of
cyanide.
to
flocculation
wastewater
Fig.
diluted
instead
as
control
After
reason
been
levels
quantities
amount cases,
with
discharge
greater
some
to
deal
total
an economic perspective
close-recycling
under
simply
companies
Prom
In
In
forbidden
metals
only
the
a given
standards
be
force
not
discharging with
pollution.
metals
meet
and
controls and
along
increases
to
effluent
concentration
been
some
but
seepage
from
these
pollution.
That
is
attracting
more
and
close-recycling
inorganic
in
solidified,
technology
wastewater
Is
one more
for
presented
in
3. Individual The
techniques
close-recycling
combination
of
many
of system
individual
the
close-recycling
of
wastewater
techniques.
process treatment Some
of
is these
a
306
It
I
307 teohnfques of
and
wastewater
1.
their
techniques
colloidal
particles
molecular
pattern
flocculation
of
since
repel
one
another
to
When
charge
(usually
of
they
have
some
all
colloida
counterthrust
force
of
takes
additives
are which of
salt
molecular
charge
I giving
Moreover.
it
with
minimum
consumption
efficient.
In
wastewater
this
is
needed
and
agent deuatering
of
of
pretreatment
with
i).
The
properties
are
shown
polymers produce
are high
rare,
molecular
of
or
a high
recommended, the
as
improved
settling
weight
is
high
links,
at
the
it
only the
is
also
is
a small
and
extremely amount
flocculation,
of
filtration
employed or
it
flocculation
molecular
treatment some
high
2.
Cationia
Table
acid quite
all
as
a
solid-liquid
effectiveness. of
in
metal hydrogen
molecular
complete
tertiary
metal
use
the
thus
some
colloidal are
particles
It
to
and
hydroxide)
and
treatment,
amazing
polymethylacrylic
of
colloida.
agents
size
colloidal
to
during
separation
The during
its
due
charge
(ferric
strongly
group
electric neutralize
the
those
is
because
a large
to
increases
force granule
opposite
added
produce
they
remains
hydrolysis
salt
agent adhesive
velocity.
to
through
in
charge,
flocculation.
hydroxide).
a large
the
2);
water
Because
particles
electric
Fig.
the
a aoattering
cm).
pattern,
achieve
ferric
(aluminum
a strong
reacts
To
have
pattern of
by but
chemical
surface
are
surface
in
flocculation
produces
here.
separated
10-4
particles
(See
soluble
-
scattering
place.
positive
ions
the
the
especially
aluminum
process
the
necessary
are
applicable,
treatment
desorlbed
flotation,
colloidal
charge)
among
oxides
in
10D7
a negative
or
force
by
scattering
a positive charge
or
1 nm which
these
their
electric
flocculation
the
are
nm are
separated
movement
gravitational
salts
than be
range
and
10
sedimentation
leas
have
Brownian and
stable.
for
metals
than
of
(flocculation
water
the
heavy
particles~blgger
traditional
the
applications
contains
by flocculation
Separation
Suspended
of
combined
whioh
and
amino
but polymers
the
molecular ester;
include
anionic
acrylamide should
flocculation
polymers
be
and
group mentioned.
non-ionic
which
can
By the
I pClyaCwlat2
CiFG&-CT~Z& --
9-1,
"above6
f---
ferric sulfLte ferrous chloride ferrous ~~_.__ gulphate.
agents
I G2P dose of jiCn -^, be avoid in abs r;;l;;ion sho*Jld 5 . I
if treatment Condition is not fa %r:~r?blc residue :'eand chromarid
I soae msin agent f,rnctionis avai-lable oolyvinyl lmine Ez cation aPPlicabi:chennegative electric charge is z 5. tfle Coa-polyvinyl pyridinetO acidic applied singly. !poly 8 g &an_ts. _ thiourea saries non-extrnon-ion e" type coa- poly acrylamide emes of acidic or -gulants ; alkaline
I
$ F vl type CCa 3 g gulants
anion
:. 5 ferro k" 2 r( -salt
1
categories
* 4 z
categoies and functLon of coagulant9
for I remarks coagulation J aluminum sulfate geneaally apolied'-jointly wiyh fe ___~. lumlnium 6-B rr0 sals to boost efficent of coa - __._r.. sodium QAation effective deckromation n .*.aluminate ~salt change in PH value of solution. alumi~um~.chlorJd~
Tab.2
309
side
link
cation
there
and
particles The
of
cost
is
of
raw
is
recover
acid
agent
from
the
silicon.
In
efficiency
be
to
complexity
of
its
easily adsorb
the them.
in
to
production
of
to
flocculation kinds
get
a high
and
and and
municipal
containing
poly-ion
and
charge high
because and
polynuclear
the
agents the
pA value
and
agents
can
compounds
particles
flocculation to
oxides. of
complex
suspended
molecular according
metals
hydrogen
flocculation
of
increase
flocculation
temperature
electric
the
also
heavy
by
molecular
Inorganic
flocculation
eliminate
wastewater
components,
to
molecular
sedimented
high
of
acid
we can
high
high
technology
molecular
sediment
and
by
density
sulfuric
a high
adding
agents.
inorganic
sedimented
recovery
wastewater
doses
of
treatment
by
while
varying
the
waste
applying
character.
produce
neutralize
fine
treatment.
quickly
to
neutralization
treat
changeable
added
by
inorganic
applied
anion,
flocculate
wastewater
membrane
flocculated
both
be
metallurgical
agents
can
Usually
its
used
significantly
flocculation
produce
in
many
can
pretreatment the
can
molecular
agents
silicon.
in
which
high
which
We have
oontaining
in
contains
flocculation
flocculants.
which effectively
low.
of
substances
molecular
used
also
wastewater
organic
to
substances
material
Application
Industrial
are
polymers
suspended
polyacrylamide ii).
a CONA2 group
non-ion
agents
nature
of
to
and can
be
the
wastewater. 2.
Exchange
Ion based
and
exchange on
the
hinge
and group
developments
in
involving special metals been
a kind hinge
to
serves resin
obtain the
chelating and dramatic
of
resins
oxidation-
of
of
have of
in
can
opened
the
into
Aere
the
the
exchanger.
Recent
up new horizons, acid
with
group hot
selectively
resins.
and
introduced
ion
weak
regeneration which
is
polymer
styrene
shape.
function
reduction
developments
molecular
group
resins
capable
high
a ball
research
double-function group
of
structure
a functional
moleoules
functional
alkaline
is
co-polymer
divinylbenzene, high
adsorption
resin
adsorb
Recently,
manufacture
and
weak
water,
of
there large
heavy have mesh,
310 multi-pore
resins
Colloidal balls (about
l-10 and
narrow
ion
affects
the
expand would
However,
as
pore
while
it
is
fine
surface
area
200-1400~.
for
be
rather is
(10 There
high
molecular
weight
adsorb
a high
and
desorb to
the
development
resin,
the
of
is
large of
following
expand
that
the
mesh,
more
and
it
has
in
resin
the
As
has
and It
resin
it
is Following
and resin
chelating in
containing
significant.
can
favorable so
by
the
heavy
The
proaess
has
applications:
a.
Condensation
b.
Elimination
and
recovery
of
high
of
low
of
metals
conaentrations
and of
reuse
impurities
of
water. in
wastewater. c. in
Elimination
wastewater d. e.
discharged
Treatment
fluctuations Seleotion
selectivity.
the
of
resin,
wastewater.
multi-pore
with
ions
adsorption.
and
wastewater
very
70.0005i).
aontraction,
organic
opaque
of of
organic and
of
a large
super-porous
expand
more
Large
groups
exchange-adsorption of
resin,
form
by
(average
and of
strength.
in
distribution
of
would
only
application. in
substances
treatment becoming
to
exchange
expansion
swell
ions
pore
easily of
treatment
function
close-recycling metals
can
resin strength
mechanical
in
hinge
greatly
mechaniaal
constituted,
colloidal of
applicable
hinge
formed
kind
freely
velocity
characteristics the
be
and
low
of
so
fine
another
can
is
and
239000-2301000P
structure
resin
would
the
of
loss
being
of
pore
its
limited
is
interstices
the
0.1
through
Modification
manufactured
particles, m2/g)
remain (below
place
resin
large
interstices
fine
there
and hinge
hard
non-consecutive
fine,
takes of
water
transparent
spaces area
usually
high
resin
fine
resin.
structure. of
surface
significant
would
its
small the
layers
very
structure in
multi-pore
balls,
the
in
without
a resin
that
characteristics;
reduced and
a co-polymer
adsorption
spaces
fine
of
numerous
a very
significantly be
mesh,
so
exchange
its
slightly such
with
fine
influences
basis of
together 11,
and
the
consists
squeezed
m2/g)
on
resin
of In
in
industrial
volume and
concentrations
and
separation
large
of
toxic
wastewater
subject
conoentration. of
substances
volumes.
metals
by
resin
to
large
311 Tab.3
Categories and characteristics of membrane and separation techniques membrane csteg3ries
electro-
dynznic function
characteristics
ion exchange
dialysis
membrane
ciiflusionperneation
permeation membrane
fine bltra;ioc
fine holl3:0.ess poly.:?r
membrane hollxnes
I,
of memxalk
ultra-filter l~~~f~~er 1
breDared
acraordarvI
o the siae moleular of-solution
V;aterselective psrma-dater permeation tian meTCrane DressuEeh d concentration dJff:er,ce 20-1C?%~/cm' f solution
1 chromium
regeneration agent NaOH
rinse water
neutralization sedimentation treated
( desalted fig.4
water water)
I I
312 f.
Elimination
of
3.
Hembrane
separation
Pending through the
permeation
a high
membrane
helps
to
separate
so In
substance
dynamic
change
of
easily Please
refer
is
as
the
in
to
Resin
in
high substances
and
pH.
The
production.
characteristics
of
esobange ions
various
aots
as
upon
the
the
is
size
resin
demonstrates
electric
oharge
while the
H+ and
those
ion
exchange
following
the
three
dynamic
resin
a high
molecules).
and
If
mind:
of
force
exchange
molecular
a molecular
water
easily, to
in
on
take
ooncentration the
is
through
introduced will
place.
osmosis,
membrane
of
By utilizing membrane
in
borne
are
osmosis
take
difference
depends for
solution
will be
permeate
permeate
of
difference
should
whioh
(easier
membrane
of of
temperature
diffusion
diffusion
exchange
permeation Ion
the
concentration
struotare
permeability;
treatment
separation
in
no
continuous
directly
the
separation
points
solution
radius
advantages:
the the
reused
3 for
of
applied
The
be
membrane,
and
fundamental
repelled.
of
or
techniques.
a result
is
for for
conaentrations of
permeability,
anionic
make kind
oamoaia
side
c.
to some
difference
following
fluotuation
Table
different
either
b.
of
to
membrane
we need
consumption;
and
can
to
the
suitable
by
separation
Diffusion
of
it
solution
membrane
hinge
components
pressure
membrane,
the
membrane
called
concentration
energy
solutions
influenced
a.
is
of
percolation
the
of
and
kind
technique
has
low
and
condensed
the
this
obtain
molecules
selectivity
concentration
through
separation
concentration
resin
solvent
the
the
difference,
phase;
operation;
place
and
difference).
Membrane
If
to
pass
wastewater.
utilize
this
(potential
pressure
solution
change
order
in
membrane,
we can
substances;
separation.
metals
techniques
of
molecular
solution,
the
organic
polymer
sieve: the
the
hydrophilic
seleotive like
enormous
diffusion
cationic
membrane
of
velocity ion
ionio
opposite of
for
membrane.
to
that
charge
of
coefficient to
Otl-,
the
are of acid
313
HNO,
radioactive waste water tank
NaOH
oh 10 edimentation * filteratio
starag
effluent (1)
trea&ent,of radioactive waste water with ion excange resin
primary purified water 990m30. 002-o. radioactive waste water 100!Z5 O.C2-0.25%
003%
lC-6micro-curie/ml
eletrodialysis primary purifie; solution secondary water 3 100~1~0.02-0.3X ;.‘2”-“o 3is lo-'micro-curie/ml 10-4mic;b_ curie/ml electfodialysis
c 'c 04 $:a
g&i% 1 ar g
?JZ IQ%
.&"E "G
treated water *9
80m' 0.0001% 10-8$licrOJ curuie/mL
l-4 namted wasteLiquid 1.2-1i'4% LO-2-LO-4microcurie/ml
,Oml 1.52.7% 10-3micro-cu.rie/mL ? / evapor&bi.on
(2) treatment of riadioactive waste water with membrane
fig.?. treatment of radioactive waste water with ion exchange resin and membrane
314 and alkali can be separated from other substances. This process is employed in olosa-recyoling
to recover acid and
alkali without consumption of eleotricity and it is very promising in application. The principle is as follows: If the concentration of the solution is greater on one side of the membrane and the size of the molecules smaller. molecules with an electric charge opposite to that of the membrane permeate through more easily. Greater physicoohemical
stability and a thinner
membrane make diffusion easier. The membrane is more efficient if the permeation pressure on the moving water is low and there is a favorable selective diffusion coefficient of the solvent molecules
(i.e. a high transport velocity and
segregation speed). Applications of diffusion-permeation a. To separate NiSO,, (CuSO,,) and recover APSO,, in metallurgical
works using the wet method.
b. To separate A12(S04) and recover P12S04 from aluminum oxide processing effluent. c. To recover chromium from electroplating d. To recover hydrofluoric
effluent.
acid and fluorosilicic
acid
from titanium and lead effluent. e. To recover hydrochloric acid from extraction or pickling liquid. f. To recover sulfuric acid from iron and steel pickling effluent. g. To recover sulfuric acid from gluaose processing liquid. In recent years. exchange-adsorption
and membrane
separation techniques have been recommended for the treatment of (a) electroplating
effluent containing chromium using ion
exchange resin (see Fig. 41; (b) radioaative liquid waste using ion exchange resin and membrane
(see Fig. 51; (c) iron
and steel work wastewater with ion exchange membrane
(see
Fig. 6); (dl Pb-wastewater with ion exchange resin and chemical process (see Fig. 71; (el cynamide wastewater with electrodialysis
process (see Fig. 8); (f) paper mill black
liquid by electrodialysis
(see Fig. 9); and (g) resin
regeneration wastewater by ion exchange resin (see Fig. 101.
315
4'residue liquid H2S04
a)g/l ti_+4+FeSO4 -Hi
FeSO4 12Og/i
&H+
I-Fe++-+ wai:er
I +
3
I
*H2S04+.
l-H2S04
c.EL2sop
l*2so4
( I' 2 %7 o+ ' 22: 16og/l 2 1 4. 2Wl 5 H2S04 ZOO-22Og/l 2 'B FeS04 180-2OOg/l
__ -+ "4 o I electrolytic
t. *cathode reac;on anode reaction y20f'H++OHH2S04~2H++S0;- ZH++SO-=-H SO 4-2 4 40H-r=0;+2H20+2 coagulant5 a-settling tank
suJp.huricacid reolenisbmut _.1 7 pickiing tank H2S04 3OOg/l FeS04 2Og/l
Fig.6. Close-recycle treatment of waste acid from iron and.steel work
_
organic Pb-waste M%fPP
-1
Fi.g.7.
Fe2(S04)3~1 roat
NaOH HCl
316
Fig.8. electrodailyaistreatment for cyamide waste water (closed system)
Cl
pH 4-6 -
b'g.9.Recovery of alkali from Paper 1~11 black liquid
317
cation exchange anion exchange resn regenerat- resin regeneration agent ion agent acid waste water (NCI+NaCI)
alkaline I waste water.I
l
'neutralization" R=N ~ discharge R=NHCI pH7.O+O low l~.~l volume weak alkali
I ~I R-COOH I SI
(NaOH+NaCl)I l weak acid lo ~i~I i.C E R
fig. i0. treatment of waste liquid from resin regeneration
--coagulant
waste water
I
*~ o
I
~a-i
Hsand
secondly treat~entF--1 c a g u ~ on
~filtrationJ I
NaOCI ]_I25U drum filtration
I HCI desalted wa~er (for reuse)
Fig.1 D m
'4
318 Tab.4.
eater 7il,zlity after electr~:~x!;al)rsi5 trc2tment
Tab.5.
Water quality
of permeated industrial water
(Pnm!
water
and
! Fe
319 4. Resin regeneration
in the treatment of wasteuater
Resin has been widely used in the production of pure water, but it has to be regenerated with acid and alkali (see Fig. 6). During the regeneration process and before discharge, wastewater neutralization
should be neutralized.
In the
process it is hard to handle pollutant
sediments without causing
environmental
some
pollution. In
order to avoid secondary polution. it is advisable to use weakly acidic resin in the treatment of neutralization effluent as it does not give any sediment in the discharge. VI. Examples of close-recycling 1. Desalination
and reuse of municipal wastewater
As municipal water supplies tend to be very tight, municipal wastewater has to be treated and reused; close-recycling
consisting of biochemical
by flocculation
and electrodialysis
treatment followed
is suitable for this
purpose, and can prevent much squandering of fresh water. In Tokyo, experimental
treatment of this kind was carried out on
over 250 m3/day of wastewater Wastewater
at the Southsand Street
Treatment Plant. the treatment capacity being
later increased (see Fig. 71. Pretreatment,
especially by 25 urn drum filtration,
eliminates microbic and ferric hydroxide pollutants and so avoids the membrane becoming clogged up, while at the same time sodium chlorate is added, and although some residue of ahlorine (about 0.5 ppm) would appear. it would not affect the membrane. Usually large pore polypropylene membrane is used and recycling with pH l-2 Cl every 30 minutes is necessary. This method is suitable for the secondary treatment of wastewater
containing 1000 ppm TDS or for the
treatment of industrial wastewater
containing 2000-4000 ppm
of TDS. In Japan this method was applied to relieve a shortage of about 900 million m3 of fresh water in the Kant0 District. 2. Vasterrater rrom chemical works Generally the wastewater
from chemical works contains
about 700-2000 ppm TDS and not a lot of organic or inorganic
320
---I
321
Tab.6. Result of ferrite treatment of Lavy metals
purifying tank
collection
industirial vater
I ultrafiltration
I
I
+
I
1-1
ion exchange
b-Iactive I
1
I
,
carbon/ 1
fig.12.
Tab.7.
result of ultra-filtration membrane treatment of eletronh3r~'ic coating material source liquid
pH
A.5
8.72
8.75
solid -_Tatter (%)___~-10 -_ amine(nor3al) conductivity $J/cm)
uf;tra-filtration reverse osmosis treated water tieated liquid
q-9 89.8
83.5
1690
2100 -
__.
..__..-!L?!.57.1 1440
322 substances
are
combination
present
of
techniques
is
organic
fresh
be
and
by fine
can
reverse
osmosis,
eliminated
be
rate
by
and
172,
membrane
after
organic
acid
3.
Wastewater
Large
so
the
(see
fror
volumes
of
from
from
processes
are
industries.
In
machinery jointly
applied
Central
Research
alkaline
containing eliminate to
water
and for
heavy
metals,
the reuse.
The
(see
Fig.
suspended water
11).
is
solids.
yeSO
is
the
added NaOB is
and
part
filtered pR value reverse micro-ohm
mixed to
with adjust
and
is
for
the sand
and
reuse of
are at
the
acidic
to of
and
is
applied is
to prior
a
by-product
process, to
and cm.
produce wastewater
electrodialysis Fe-0 acidic
and
eliminate
adjusted.
the
wastewater
neutralization,
the
wastewater
industries
electrodialysis
process
per
the
by
electrical
combined
osmosis
of and
metals,
alkaline
by
of
drop
regenerated
treatment
by
will
iron
heavy the
for
be
compounds
machinery
process
except
first
0.1
added
Fe-0
can divalent.
5).
water
are
technical
is
pollutants
treatment
the
overall
the
The
be
By
of
membrane
of
followed
by
being
the
metals,
the
generated
conductivity metals,
In
of
In
technique,
wastewater
Fe-O
exchange
year
the
and in
techniques
reuse.
heavy
close-recycling alkaline
ion
water
nitrogen
and
acidic
In
the
and
can
l/2.
salts 99% of
containing
treatment
by
one
4 and
Japan,
COD (Hn)
calcium,
generated
Institute.
osmosis pure
19%.
membrane
and
the
wastewater,
reverse extra
by
silicate,
electrical
boilers,
in
by
Tables
the
solids sand
and
After
to
by
solution
silicate
eliminate
suspended
filtration
ions.
wastewater
wastewater daily
total
years of
rinsings
by
elimination
mainly
substances,
oxalic
the
91% of
three
consist
and
eliminated.
of
to
possible
By flocculation, 2/3,
of
be
is
sedimentation,
monovalent
ions).
the
operation.
by
osmosis
possible
of
a
reverse
entirely
961
flocculation,
of
can
not
It
than
filtration.
NE4-N)
is
use
More
95-971
multivalent
it
Industrial
reduced
(95-961
(N03-N.
as
using and
eleotrodialysis.
for
eliminated
filtering
Close-recycling filtration
methods.
content
and
by
water
physicochemical aan
it.
recommended,
substances
obtain
in
flocculation,
and ion In
extra
the
seoonh
containing
pE value
pure
exchange.
to
its part,
heavy 10.
the
323
1
. watei resin coating matelrial
extra-filtration
/ reverse
1
1
osmosis
fig. 13.
F-on
electro-
plating tank
1
vacua condensatio cooling water
1
condensed liquid
sludge
9
chromium eletro?latin tank
cwles6er3
NiSO4
r-=
fig. 14.
recovery
/L
regematian
ion exchange
I
concentratedNISO,
I
Fig. 15.
324
temperature generate
Is
separation 6.
are
ferrite wave
out,
in
can
with
the
be
blown
can
used
in
to
solid-lfquid
shown
reduce be
in
and
results
to
produotlon
also
is
in
salt
carried
magnetia
Table
content out
body
to
and
or
the
electric
Yastewater from the automobile Industry
In the systems,
automobile where
separately. water the
motor
can
teohniques. tons
of
It
teohnologiaal in
suspended
solids of
eliminate part there
is
paints and
the
can
be
ratio
per
to
meet
12. in
is
5.
the
13).
aontains
is
the
suspended
and
13-331
Wastemater amount industry
organic are
the
in
the
of
heavy
metals
its
the
was
discharged
It
part
in (3)
treatment
its
which
it
BOD is solids,
pg
value
The
results
7,
which
ooating
soluble
is
its 6-9.
and
of shows
material
that
are
solids.
industry
industry contains. after
to
3;
electrophoretlc
Table
eleotroplatlng it
to
after
color,
from the eleetroplatlmg
from
used
coating;
non-volatile
in
total
is 30 in
osmosis
substances.
solids of
from
of a high
membrane
Ohm,
given
is
a lot with
example,
10s
The
eleotrophoretic
milky
1.000-2r000
recovery
are
totally;
reverse of
hundred
12,000-14,000
flotation
reused
For
two
treatment
BOD drops
from
a liquid
numerous
Wastewater the
Fig. it
only
ultrafiltration by
is
be
In
close-reoyoling
wastewater upward
as and
thousand
requirements.
there
and water
by
(see
(1)
domestio
treated
mg/l,
eliminated
part
can
is
wastewater
pressure
rinsing
recovered
and
of
the
this
substances,
resistance
99.82
In
High
material
treatment
day
for
mainly
contains
of
water
water
4.000-6.000
help
replenish
cooling
reused
the
reused
painting
fifty
consumption
two
treated
ultrafiltration.
to
Fig.
water
coating
With
is
and
manufactures
water
by
are
wastewater
after
Co.
oonoeyed
recycled,
necessary
BOD.
are
reused
and
day.
is
is
wastewater
is
micro
(2)
be
process
presented
water
Automobile
per
fresh
content
also
daily,
tons
wastewater industrial domestic
oooling
Nissan
vehicles
thousand
and
treatment,
water,
rinsing Japan,
Industry,
domestic
After
industrial
of
air
separation
absorption.
4.
for
‘,C,
magnet
electrodialysis
reuse
residue
60-70
then
carried by
ppm for
to
and
Desalination
(500
it
raised
ferrite,
is In
only
the
notorious early
neutralization
days
325 which
treatment, the
ion
caused
exchange
rinsing
water
has
been
reuse.
and
liquid
regeneration
undergoes
electrodialysis
or
interim
reverse
process
all
salts;
these
technological
wastewater
at
the
rinsing
wastewater
at
the
shifting
involve
a combination
diffusion
membrane
Recovery In Cr3+
the and
which
of Fe*+
membrane
while
Fe,
hydroxide the
will
also is
of
Reusing In
The
the
concentration
the
methods
generally
reverse vacuum
osmosis,
evaporation
and
be
high
concentration, to
the the
the
chromate
in by
anode
the
into
electroplating
tank
cathode,
and
Cr
Part 6+
vacuum
for
the
by
for
anode
chamber, react
tank
electroplating
in
will
eliminated.
the
isolated
cathode
solution
after
between
for
the
of
solution,
(cations) to
oxidized
rinsing
the
chamber
by
and
a residue
recycling
impurities
produced
to
chromium
liquid
membrane
generated will
is
concentration
concentration
process.
chromate
back
to
recover
whole
treatment. low
high
waste
the
the
ions
be
conveyed conveyed
and the
Recovery
replaced
and
Cu in
solution
conveyed water
Zn.
involves
accumulates
through
radical
compound in
tank
pass
close-recycling
electrodialysis.
regularly
electrolysis.
chamber
covering
electroplating
gradually
electroplating
crystallize
the
chromium from
be
to
exchange.
of
electrolysis.
chromium
should
treatment
membrane
a distillation-
at
and
Now
by
before
stage.
ion
the
from
mainly stage
of
permeation,
isolated
aimed
with
wastewater
in
waste
concentration
applied
are
pollution.
adopted
osmosis,
is
steps
process
Electroplating
environmental
process for
concentration
severe
of the
with
hydroxide 3+ Cr
the
anode
reuse.
and
Rinsing
concentration,
tank,
and
cooling
reuse
(see
Fig.
is water 14).
liquid electroplating condensed
by
process, vacuum
liquid
evaporation
of
low
or
I
1 H2S04 FeS04
the
Pig.16.
326
eleotrodialysis.
and
electroplating liquid)
is
reused
after
is
regenerated
to
ion by
condensed
while
conveyed
be
process,
the
tank
the
acid during
regeneration.
after
vacuum
evaporation
(or
tank.
the
See
desired)
flowchart
in
water
Fig.
salt
in
the
the
solution,
osmosis
to
oan resin
permeation
salt
reverse
conveyed
the
exchange
nickel
Nickel
after
is
Rinsing Cation
from
to
concentration
By a diffusion
solution
is
tank.
separated
waste
concentration
conveyed
(low
treatment. acid.
is
is
water
recovery
exchange sulfuric
sulfuric
liquid
cooling
if
a high
electroplating
15.
Acid reooverp tror an acid rinsing tank In falls
the
acid
due
to
solution.
The
separate
free
sulfate
is
membrane ions on
the
permeation
acid
ferrous to
on the
side
Fig.
method ion
(pure side,
and
gradually metals
can
be
in
used
solution.
cathode
membrane
(see
other
sulfate
metal the
efficiency and
Fe
Ferrous
iron)
by
isolated
sulfuric
sulfuric
the
to
radical
acid
is
collected
161.
Conolusion
they
close-recycling been
only
control
i.e.
technological
basis
manufacturing the
(closed)
ion
all
objectives
of are
membrane
of
greater realized.
the
made
easy. not
have
process),
relationship over
in
the
soda
(using sulfide),
soda
produotion
non-aqueous
electroplating
processes
etc. efforts in
to
Innovations all
sodium
grade
non-aqueous
close-recycling fully
and
manufacturing
(high
eleotroplating)t still
problems
as
technical
control. be
that
olose-recycling
instead
mercury
systems,
make
wastewater
into
paper alkali
exchange
static
to
only
though point
all task,
other
wastes”
research
without
dyeing
(ionizing us
and
many
analysis,
“three
pollution-free dioxide
been
organization,
continue
of
not
sophisticated
also
benefit and
processes
technology: chlorine
but
have
and
a technological
really
a very
above
treatment
from
has is
cost
recommended
wastewater
technical
production the
in
difficult
techniques
administration,
using
very
control
considered,
on
use
application
wastes”
world
to
seem
their
between
techniques
put
may not view,
“Three
Let
from
through
recently
be
acidic of
diffusion
transferred
anode
The
of
process
accumulation
electrolysis
pass
VII.
rinsing the
the
to
ensure
treatment
that of
the
industrial