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VC seawater desalination plant
Desalination, 45 (1983) 39-47 Elsevier Science Publishers B.V., Amsterdam
OPERATING
EXPERIENCE
VTE/VC SEAWATER
B. Ohlemann,
AND PERFORMANCE
DESALINATION
Envirogenics
DATA OF AN ADVANCED
BARGE-MOUNTED
PLANT
Incon Anlagentechnik
D.K. Emmermann,
39 - Printed in The Netherlands
GmbH, Homburg/Saar
Systems
Co., El-Monte,
California
ABSTRACT The floating desalination demonstration plant "MEDA" presents an advanced concept to produce fresh water from seawater with low energy consumption. At first step of its demonstration phase, MEDA was operated at Helgoland in the North-Sea at its design capacity of 5000 ma/day and a performance ratio of 22 to 1 kg/kg. The 24 effect VTE evaporator combined with two vapor compression topping effects operated at a max. feed temperature of 135 "C with sulphuric acid pretreatment. High heat transfer rates were obtained using foamy upflow in double-fluted evaporator tubes without inter-effect pumps. Data were obtained for an alternative pretreatment system for feed make-up using a fluidized bed ion exchanger system operating in the countercurrent mode. Calcium ion content in the feedwater was demonstrably reduced by more than 90 %. This paper presents and analyses the above performance results.
RESUME L'installation flottante demonstrative de desalenisation d'eau de mer "MEDA" a' l'avantage de produire, par l'intermediaire d'un concept trds avance avec peu d'energie, de l'eau potable. Lors de la l&e @tape demonstrative qui a &ti! effectuee en Helgoland, en mer du Nord. M@da montra une capacite de 5000 m3/h et un ratio de performance de 22 a' 1 kg/kg. L'evaporateur 24-Effet-aux tuyaux verticaux avec le condensateur de vapeurs chaudes a et6 opere avec une temperature maximale de l'eau atteignant 135 "C avec la mgme dose d'acide sulphurique le tartre. L'utilisation d'evaporation d'ecume par sustention et de tuyaux aux rainures verticales dans les evaporateurs aux tuyaux verticaux a prouve une augmentation nette des resultats du transfer de chaleur, sans utilisation des pompes inter-effet. Les donnees ont et.5 effect&es pour un systeme alternatif preventif pour la preparation d'eau potable utilisant un systeme d'echange d'ions a' base de fluor operant contre courant. Le contenu en calcium pour cette eau d'alimentation etait reduit de plus de 90 %. Cette explication presente et analyse des resultats de ce procedus.
KURZFASSUNG Die verschwimmbare Meerwasserentsalzungsund Demonstrationsanlage "MEDA" prasentiert ein fortschrittliches Konzept zur Gewinnung von Brauchwasser aus Meerwasser. Der erste Schritt umfaDte die Demonstration der MEDA in der Nordsee vor Helgoland mit der Auslegungskapazitat von 5000 m3/d und einem Leistungsverhlltnis von 22 : 1 kg/kg. Die 24-Effekt-Vertikalrohrverdampferanlage kombiniert mit zwei Briidenverdichtereffekten wurde mit einer maximalen Speisewassertemperatur von 135 'C bei gleichzeitiger Dosierung von Schwefelslure zur Kesselsteinverhijtung betrieben. Die Anwendung von Schaumauftriebverdampfung und Llngsrillenrohren in den Vertikalrohrverdampfern ergab eine betrgchtliche Steigerung der Warmedurchgangszahlen ohne Einsatz von Intereffektpumpen. Daten wurden aufgeOOll-9164/83/$03.00
0 1983 Elsevier Science Publishers B.V.
40 nommen fiir eine nach dem Liftbett-Verfahren arbeitende Ionenaustauscheranlage als alternatives System zur Verhiitung von Kesselsteinablagerungen. Der Kalziumgehalt des Speisewassers konnte urn Uber 90 % reduziert werden. Die vorliegende Abhandlung prasentiert und bewertet die erhaltenen Betriebsdaten.
INTRODUCTION The principle operational
aim of the MEDA project
reliability
desalination
is to demonstrate
and a low energy consumption
plant "MEDA" which presents
an advanced
water from seawater.
This has been achieved
with the combination
of well-known
pression
(VC), vertical
efficiency
TECHNICAL
necessary
plant is a VC-VTFE-MSF
equipment
(VTFE) and multi-
desalination
plants.
fired boiler,
the necessary
has been designed
supply of the desalination
whereby
the high pressure
the vapor compressor electricity
from a central
With the features
control
outlined
by an oil
through a turbine
Plant operation
and accommodation
provide
is remotely
con-
a workshop,
for operating
seawater
as well
continuous
diesel generators
room. The barge also contains
above, the floating
all
hose. The storage
for one month's
steam is expanded
for plant start-up.
can be put in operation local conditions
and distillate
plant is provided
and a generator.Three
storage for spare parts, a laboratory
of 5000
unit. This includes a seawater
fresh water to land using a flexible
The energy
capacity
on a barge which also contains
tanks for fuel, chemicals,
for fuel and chemicals
operation.
unit with a nominal
It is installed
storage
as a pump to transfer
trolled
system
vapor com-
process with a total
thermal
to make it a self-supporting
intake with screens,
driving
fresh
FEATURES
(1.3 mgd) fresh water.
capacity
to produce
processes:
is a desalting
seawater
a new desalting
with foamy upflow
(MSF). The result
2 to 3 times higher than conventional
The desalting m3/d
concept
by developing
and proven thermal
tube evaporation
stage flash evaporation
the feasibility,
of the floating
desalination
in a very short time, almost completely
personnel. plant "MEDA"
independent
of
and facilities.
PROCESS DESCRIPTION The basic details process diagram topping
of the process
is presented
(vapor compression)
ly oriented
feed heater
have been given elsewhere
in Figure 3. The VC/VTFE effects and twenty-four
is located
(ref. 1). A
unit consists
VTFE effects.
in each VTFE effect,
except
of two
One vertical-
in effect twenty-
four. A trim heater is used to heat the feed water up to the top brine temperature. The vapor generated denser.
in effect
Brine and distillate
twenty-four
is further
brine cooler also serves as precondenser densable
gases are removed
cooled
is condensed
in the reject con-
in a three stage MSF cooler. The
for the venting-system
by a water ring vacuum pump.
before non-con-
41 Raw seawater denser.
High pressure
as cooling
water
seawater
is utilized
by the vapor compressor
of the total distillate
turbine
is used to generate
turbine
generator
output.
electrical
effect.
Both quantities
the topping
is condensed
effects.
Vapor generated
The bus
steam is uti-
in the first VTFE effect. in the first topping
(vapor compres-
this effect with the top brine
and flows as heating
of condensed
by the
to a common
The turbine exhaust
Part of the feed water entering
is evaporated
The
a large per-
with the diesel generators
lized as main heat input and is condensed
sion) effect.
and produces
Part of the power produced
power can be transferred.
Steam from the compressor
in the system.
through a turbine.
power up to 875 kVA at 50 cycles.
can be synchronized
so that electrical
temperature
in the MSF cooler and reject con-
is used as feed water
steam of 50 bar and 505 "C is expanded
power provided centage
is utilized
Part of the preheated
steam to the second
topping
steam form the total amount of product in topping
in
effect two flows to the compres-
sor. OPERATION
AND PERFORMANCE
After construction
the system were carried conditions
DATA
in the North Sea shipyard
was completed
out at the port of Emden. Because
at the Emden docks,
several
tests of
of the brackish
the barge was towed to Helgoland,
water
an island 70 km
off the German North Sea coast. The floating conditions.
seawater
desalination
An initial set-back
(a) The injection
plant was operated
in plant operation
pumps of the diesel generators
from the specification
in the electrical
a self-acting
several
installation,
boiler
week of operation.
trips.
Thereafter
Both problems
No problems termined
arose with the seawater
during operation,
matter
of the fuel oil pump
filter
including
installed
with a quantity
pumps worked
properly,
pump serving
the ion exchanger
Electrical brine cooler
equipment
worked
continuous
while operating
tubing materials
less steel claddings
in the feed make-
except for failure
operation
satisfactorily,
gave false level signals.
the level transducer Various
effecting
system.
of a pack-
The packing
of the desalination
unit.
only the level float in the MSF
This problem was eliminated
brine control
no. 1.4439/1.4571)
by cleaning
valve manually.
(CuNi 70/30, CuNi 90/10, Al-Brass)
(Material
screen. As de-
in the local seawater.
All process and metering
without
the first
of about 20 ma/h due to a
ing of the brine regenerant was replaced
during
running up to the end
problems.
intake system,
the self-cleaning
up line had to be rinsed continuously high level of suspended
shut-down
were eliminated
operational
of the quality
and (b) due to an error
the plant was continuously
of the test period with only negligible
by two problems:
failed because
of the fuel used which differed
created
for 30 days in seawater
was caused
and rubber
as well as stain-
lined piping caused
42 no problems.
Some corrosion
was noticed
No scaling at all was observed
in the carbon
neither
steel MSF cooler.
in the evaporator
tubes nor in the
feed heater tubes. Surfactant subsequent
dosing did not cause any operating
multi-stage
operation
MEDA was operated test sequence formance
flash brine cooler.
due to barge movement
was carried
at design conditions
obtained TABLE
before an extensive
out in order to obtain additional
operating
cooling
inlet temperature
water and/or
under these operating
data on system per-
conditions.
To meet the design point, a seawater ed by recirculating
There was also no effect on plant
even in stormy weather.
continuously
under various
problems with regard to the
product water.
conditions
are summarized
of 30 'C was simulat-
Plant performance in Table
data
1.
1
Performance
data Helgoland
Product water:
Economy
flow rate
m3/d
5250
ppm
<25
ratio a
electrical
Max. operating
1982
TDS
Spec. fuel consumption Overall
August/September
b
.
power consumption
kg dist/kg
steam
22.3
kg oil/m3 dist
3.9
kW
550
temperature
"C
135
kg/h
270 000
330 000
Cooling water temperature
kg/h "C
Seawater
temperature
OC
15
Seawater
concentration
pw wm
33 500
Feed water rate Cont. factor Cooling
5
water rate
Surfactant
(~0s)
dosing rate
One stage radial compressor
30
IO
with inlet guide vane:
Volume flow
m3/s
6.2
Suction
pressure
bar
2.60
Suction
temperature
"C
128.8
kW
400
Pressure
ratio
1.22
Power consumption
(shaft)
Speed
min
-1
7375
EAt steam conditions of 50 bar and 505 "C Including overall electrical power consumption The economy
ratio under design conditions
ure steam of 50 bar and 505 'C and includes
has been calculated the electrical
at high pres-
power provided
by
43 the turbine actual
driven generator.
primary
energy
the desalination
The specific
demand.
plant as well as the overall
pumps, etc. and all auxiliaries The feed water entering centration
ratio enables
ment systems liquid
process
at an increased
possible
The addition the scaling there
of 10 ppm surfactant
design
tubes of various
An alternative the partial
process
removal
sists of five identical
pumps. Vertical
operated
in parallel
to remove suspended (blow-down)
supplied
seawater
whole system
is self-acting
The ion exchanger
hardness desired
start-up
Figures
by ion exchanger
by the evaporator
and controlled
with double
heat trans-
to avoid scaling
involving
The system con-
The third column was backwashed with concentrated
unit. The last column was rinsed again. The
by micro-processor. within
number of cycles were required
level. The successful
linked
heat transfer
and feed heater.
the filter was ready for operation
in the feed water and finally
the removal
overall
for effects
of
brine as
have been equipped
column was regenerated
system was put into operation
a certain
in a reduction
to overall
was tested.
ratio.
each filled with 20 m' resin. Two columns
Another
before
made it
performance
tube foam evaporation
4 and 5 present
for feed water softening. solids.
the multi-effect
tube evaporation
of feed water pretreatment
with treated
initial
utilizing
increase
under design conditions
vessels
a smaller
drop in the evaporating
gave a significant
of Calcium
Furthermore
to the feed water results
materials.
obtained
5-fold. This condosing and pretreat-
hence the overall
(ref. 2, 3, 4, 5). Effects and feed heaters
fer coefficients
for
of 135 'C. These facts and the
with vertical
and tube side pressure
tube geometry
supply for
time.
temperature
is no need for inter-effect
fluted
brine
was concentrated
the number of effects
tendency
with advanced rates
operating
energy
power consumption
in costs for chemical
an evaporator
of foamy upflow combined
to increase
electrical
volumes and pump sizes.
start-up
realized
is based on the
the thermal
on the barge.
the evaporator
a reduction
reduces
The MEOA project
application
utilized
as well as vessel
inventory
fuel consumption
This incorporates
in the regenerating
one hour. After until the residual brine reached
the
operation of the ion exchanger system resulted in 2+ 2+ and 70 % Mg . Calcium content in the treat-
of more than 90 % Ca
ed feed was measured
by atomic
sorption
that such systems
can be applied
brine temperature
of 135 "C and above.
in the on board laboratory.
for operating
without
acid-dosing
This shows at a maximum
CONCLUSIONS The practical
feasibility
of advanced
desalting
technology
as presented
on a full-scale
production
size plant. This
has been successfully
demonstrated
has also demonstrated
that performance
process are achievable.
ratios 2 to 3 times higher
This will result
in considerable
benefit,
here
than MSF in that over-
44 all costs on large scale desalination successful VTFE
demonstration
plants can be substantially
of MEDA at Helgoland
or VTFE for single and dual purpose
supports
reduced.
the acceptance
The
of VC/
plants.
ACKNOWLEDGEklENTS The authors generous
and Incon Anlagentechnik
financial
support
(BMFT) of the Federal
Republic
ment. They are also indebted seewerke
GmbH, without
ions to the execution
GmbH, acknowledge
of the Ministry
for Research
with gratitude
of Germany as well as their continuous
to Incon's Joint Venture
whose active
involvement,
the
and Technology
partner,
Thyssen
from inception,
encourageNord-
and contribut-
of the work, the MEDA project may not have been realized.
REFERENCES
1 2 3 4 5
D.K. Emmermann, An advanced barge mounted VTE/VC for the desalination of seawater,'International Congress on Desalination and Water Re-Use, Bahrain Nov. 29 - Dec. 3, 1981 E. Kirschbaum et al: WarmeUbergang im senkrechten Verdampferrohr, VDI Forschungsheft 375, 193-i. E. Kirschbaum, Der WarmeUbergang im senkrechten Verdampferrohr, Chem. Ing. Techn. Nr. 1, 1954 E. Kirschbaum, Der WPrmeUbergang im senkrechten Verdampferrohr, Chem. Ing. Techn. Nr. 5, 1955 H.H. Sephton, Development of vertical tube foam evaporator for desalination, OWRT report - PB-248 667, June 1975
Fig. 1. Barge-mounted VC/VTFE seawater capacity of 5000 m'/day fresh water.
Fig. 2. Plant operation
is remotely
desalination
controlled
plant MEDA with a nominal
from this central
room.
HP-steam from boiler
Feed water
pretreatment
f---------1
I
t
loo-qf~12 6
Vapor compression
I
I
I
I---J
cycle
I
1
I
I
I
I r--I
1 I
I I
I I
7
:
'31
MSF -
16 .
evaporator
1 Seawater intake 2 Reject condenser 3 Cooling water discharge L Ion exchanger 5 Decarbonator
system
7 Feed water pump 0 Feed water to topping effect 1 9 Vapor compression effect Is.1 10 Compressor 11 Turbine I Generator
3.
Process
12 HP-steam by-pass 13 LP-steam to 19 VTFE-effect IL Distillate out off V&nit 15 Brine to 1st VTFE-effect 16 Distillate to MSF-unit 17 Brine to MSF-unit
6 Deaerator
Fig.
17
diagram
18 Non-condcnsiblcs
from VTFE-unit
19 Blow down 20 Product water 21 Vacuum pump 22 Steam condensate
pump
2 i
_II-w
Loo0
v 2000 5 r c1 z 1000
*
.
% I” 0
Fig.4
1
“‘.’ 1 2
3
1
5
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 No. of feed heoter
tubes based on outside
range 45 - 135 "C, average
Fig.5.
8
. Overall heat transfer coefficients
with double-fluted
z ii
7
6
0
',.""."""."'.",.' 1 2 3 L 5 6 7
Overall
on outside
velocity
heat transfer
tube diameter
loading 4 l/min/tube,
0
for vertically tube diameter
oriented
feed heater
of 19 mn. Temperature
1.5 m/s, tube wall thickness
0.9 mm.
9 IO ll 12 13 IL 15 16 17 18 19 20 21 22 23 2.L Na of VTFE -Effect
coefficients
for vertical
of 50 mm. Temperature
10 ppm surfactant,
tube foamy upflow
range 50 - 130 "C, average
tube wall thickness
0.9 mn.
based liquid
OPERATING
EXPERIENCE
VTE/VC SEAWATER
B. Ohlemann,
AND PERFORMANCE
DESALINATION
Envirogenics
DATA OF AN ADVANCED
BARGE-MOUNTED
PLANT
Incon Anlagentechnik
D.K. Emmermann,
39 - Printed in The Netherlands
GmbH, Homburg/Saar
Systems
Co., El-Monte,
California
ABSTRACT The floating desalination demonstration plant "MEDA" presents an advanced concept to produce fresh water from seawater with low energy consumption. At first step of its demonstration phase, MEDA was operated at Helgoland in the North-Sea at its design capacity of 5000 ma/day and a performance ratio of 22 to 1 kg/kg. The 24 effect VTE evaporator combined with two vapor compression topping effects operated at a max. feed temperature of 135 "C with sulphuric acid pretreatment. High heat transfer rates were obtained using foamy upflow in double-fluted evaporator tubes without inter-effect pumps. Data were obtained for an alternative pretreatment system for feed make-up using a fluidized bed ion exchanger system operating in the countercurrent mode. Calcium ion content in the feedwater was demonstrably reduced by more than 90 %. This paper presents and analyses the above performance results.
RESUME L'installation flottante demonstrative de desalenisation d'eau de mer "MEDA" a' l'avantage de produire, par l'intermediaire d'un concept trds avance avec peu d'energie, de l'eau potable. Lors de la l&e @tape demonstrative qui a &ti! effectuee en Helgoland, en mer du Nord. M@da montra une capacite de 5000 m3/h et un ratio de performance de 22 a' 1 kg/kg. L'evaporateur 24-Effet-aux tuyaux verticaux avec le condensateur de vapeurs chaudes a et6 opere avec une temperature maximale de l'eau atteignant 135 "C avec la mgme dose d'acide sulphurique le tartre. L'utilisation d'evaporation d'ecume par sustention et de tuyaux aux rainures verticales dans les evaporateurs aux tuyaux verticaux a prouve une augmentation nette des resultats du transfer de chaleur, sans utilisation des pompes inter-effet. Les donnees ont et.5 effect&es pour un systeme alternatif preventif pour la preparation d'eau potable utilisant un systeme d'echange d'ions a' base de fluor operant contre courant. Le contenu en calcium pour cette eau d'alimentation etait reduit de plus de 90 %. Cette explication presente et analyse des resultats de ce procedus.
KURZFASSUNG Die verschwimmbare Meerwasserentsalzungsund Demonstrationsanlage "MEDA" prasentiert ein fortschrittliches Konzept zur Gewinnung von Brauchwasser aus Meerwasser. Der erste Schritt umfaDte die Demonstration der MEDA in der Nordsee vor Helgoland mit der Auslegungskapazitat von 5000 m3/d und einem Leistungsverhlltnis von 22 : 1 kg/kg. Die 24-Effekt-Vertikalrohrverdampferanlage kombiniert mit zwei Briidenverdichtereffekten wurde mit einer maximalen Speisewassertemperatur von 135 'C bei gleichzeitiger Dosierung von Schwefelslure zur Kesselsteinverhijtung betrieben. Die Anwendung von Schaumauftriebverdampfung und Llngsrillenrohren in den Vertikalrohrverdampfern ergab eine betrgchtliche Steigerung der Warmedurchgangszahlen ohne Einsatz von Intereffektpumpen. Daten wurden aufgeOOll-9164/83/$03.00
0 1983 Elsevier Science Publishers B.V.
40 nommen fiir eine nach dem Liftbett-Verfahren arbeitende Ionenaustauscheranlage als alternatives System zur Verhiitung von Kesselsteinablagerungen. Der Kalziumgehalt des Speisewassers konnte urn Uber 90 % reduziert werden. Die vorliegende Abhandlung prasentiert und bewertet die erhaltenen Betriebsdaten.
INTRODUCTION The principle operational
aim of the MEDA project
reliability
desalination
is to demonstrate
and a low energy consumption
plant "MEDA" which presents
an advanced
water from seawater.
This has been achieved
with the combination
of well-known
pression
(VC), vertical
efficiency
TECHNICAL
necessary
plant is a VC-VTFE-MSF
equipment
(VTFE) and multi-
desalination
plants.
fired boiler,
the necessary
has been designed
supply of the desalination
whereby
the high pressure
the vapor compressor electricity
from a central
With the features
control
outlined
by an oil
through a turbine
Plant operation
and accommodation
provide
is remotely
con-
a workshop,
for operating
seawater
as well
continuous
diesel generators
room. The barge also contains
above, the floating
all
hose. The storage
for one month's
steam is expanded
for plant start-up.
can be put in operation local conditions
and distillate
plant is provided
and a generator.Three
storage for spare parts, a laboratory
of 5000
unit. This includes a seawater
fresh water to land using a flexible
The energy
capacity
on a barge which also contains
tanks for fuel, chemicals,
for fuel and chemicals
operation.
unit with a nominal
It is installed
storage
as a pump to transfer
trolled
system
vapor com-
process with a total
thermal
to make it a self-supporting
intake with screens,
driving
fresh
FEATURES
(1.3 mgd) fresh water.
capacity
to produce
processes:
is a desalting
seawater
a new desalting
with foamy upflow
(MSF). The result
2 to 3 times higher than conventional
The desalting m3/d
concept
by developing
and proven thermal
tube evaporation
stage flash evaporation
the feasibility,
of the floating
desalination
in a very short time, almost completely
personnel. plant "MEDA"
independent
of
and facilities.
PROCESS DESCRIPTION The basic details process diagram topping
of the process
is presented
(vapor compression)
ly oriented
feed heater
have been given elsewhere
in Figure 3. The VC/VTFE effects and twenty-four
is located
(ref. 1). A
unit consists
VTFE effects.
in each VTFE effect,
except
of two
One vertical-
in effect twenty-
four. A trim heater is used to heat the feed water up to the top brine temperature. The vapor generated denser.
in effect
Brine and distillate
twenty-four
is further
brine cooler also serves as precondenser densable
gases are removed
cooled
is condensed
in the reject con-
in a three stage MSF cooler. The
for the venting-system
by a water ring vacuum pump.
before non-con-
41 Raw seawater denser.
High pressure
as cooling
water
seawater
is utilized
by the vapor compressor
of the total distillate
turbine
is used to generate
turbine
generator
output.
electrical
effect.
Both quantities
the topping
is condensed
effects.
Vapor generated
The bus
steam is uti-
in the first VTFE effect. in the first topping
(vapor compres-
this effect with the top brine
and flows as heating
of condensed
by the
to a common
The turbine exhaust
Part of the feed water entering
is evaporated
The
a large per-
with the diesel generators
lized as main heat input and is condensed
sion) effect.
and produces
Part of the power produced
power can be transferred.
Steam from the compressor
in the system.
through a turbine.
power up to 875 kVA at 50 cycles.
can be synchronized
so that electrical
temperature
in the MSF cooler and reject con-
is used as feed water
steam of 50 bar and 505 "C is expanded
power provided centage
is utilized
Part of the preheated
steam to the second
topping
steam form the total amount of product in topping
in
effect two flows to the compres-
sor. OPERATION
AND PERFORMANCE
After construction
the system were carried conditions
DATA
in the North Sea shipyard
was completed
out at the port of Emden. Because
at the Emden docks,
several
tests of
of the brackish
the barge was towed to Helgoland,
water
an island 70 km
off the German North Sea coast. The floating conditions.
seawater
desalination
An initial set-back
(a) The injection
plant was operated
in plant operation
pumps of the diesel generators
from the specification
in the electrical
a self-acting
several
installation,
boiler
week of operation.
trips.
Thereafter
Both problems
No problems termined
arose with the seawater
during operation,
matter
of the fuel oil pump
filter
including
installed
with a quantity
pumps worked
properly,
pump serving
the ion exchanger
Electrical brine cooler
equipment
worked
continuous
while operating
tubing materials
less steel claddings
in the feed make-
except for failure
operation
satisfactorily,
gave false level signals.
the level transducer Various
effecting
system.
of a pack-
The packing
of the desalination
unit.
only the level float in the MSF
This problem was eliminated
brine control
no. 1.4439/1.4571)
by cleaning
valve manually.
(CuNi 70/30, CuNi 90/10, Al-Brass)
(Material
screen. As de-
in the local seawater.
All process and metering
without
the first
of about 20 ma/h due to a
ing of the brine regenerant was replaced
during
running up to the end
problems.
intake system,
the self-cleaning
up line had to be rinsed continuously high level of suspended
shut-down
were eliminated
operational
of the quality
and (b) due to an error
the plant was continuously
of the test period with only negligible
by two problems:
failed because
of the fuel used which differed
created
for 30 days in seawater
was caused
and rubber
as well as stain-
lined piping caused
42 no problems.
Some corrosion
was noticed
No scaling at all was observed
in the carbon
neither
steel MSF cooler.
in the evaporator
tubes nor in the
feed heater tubes. Surfactant subsequent
dosing did not cause any operating
multi-stage
operation
MEDA was operated test sequence formance
flash brine cooler.
due to barge movement
was carried
at design conditions
obtained TABLE
before an extensive
out in order to obtain additional
operating
cooling
inlet temperature
water and/or
under these operating
data on system per-
conditions.
To meet the design point, a seawater ed by recirculating
There was also no effect on plant
even in stormy weather.
continuously
under various
problems with regard to the
product water.
conditions
are summarized
of 30 'C was simulat-
Plant performance in Table
data
1.
1
Performance
data Helgoland
Product water:
Economy
flow rate
m3/d
5250
ppm
<25
ratio a
electrical
Max. operating
1982
TDS
Spec. fuel consumption Overall
August/September
b
.
power consumption
kg dist/kg
steam
22.3
kg oil/m3 dist
3.9
kW
550
temperature
"C
135
kg/h
270 000
330 000
Cooling water temperature
kg/h "C
Seawater
temperature
OC
15
Seawater
concentration
pw wm
33 500
Feed water rate Cont. factor Cooling
5
water rate
Surfactant
(~0s)
dosing rate
One stage radial compressor
30
IO
with inlet guide vane:
Volume flow
m3/s
6.2
Suction
pressure
bar
2.60
Suction
temperature
"C
128.8
kW
400
Pressure
ratio
1.22
Power consumption
(shaft)
Speed
min
-1
7375
EAt steam conditions of 50 bar and 505 "C Including overall electrical power consumption The economy
ratio under design conditions
ure steam of 50 bar and 505 'C and includes
has been calculated the electrical
at high pres-
power provided
by
43 the turbine actual
driven generator.
primary
energy
the desalination
The specific
demand.
plant as well as the overall
pumps, etc. and all auxiliaries The feed water entering centration
ratio enables
ment systems liquid
process
at an increased
possible
The addition the scaling there
of 10 ppm surfactant
design
tubes of various
An alternative the partial
process
removal
sists of five identical
pumps. Vertical
operated
in parallel
to remove suspended (blow-down)
supplied
seawater
whole system
is self-acting
The ion exchanger
hardness desired
start-up
Figures
by ion exchanger
by the evaporator
and controlled
with double
heat trans-
to avoid scaling
involving
The system con-
The third column was backwashed with concentrated
unit. The last column was rinsed again. The
by micro-processor. within
number of cycles were required
level. The successful
linked
heat transfer
and feed heater.
the filter was ready for operation
in the feed water and finally
the removal
overall
for effects
of
brine as
have been equipped
column was regenerated
system was put into operation
a certain
in a reduction
to overall
was tested.
ratio.
each filled with 20 m' resin. Two columns
Another
before
made it
performance
tube foam evaporation
4 and 5 present
for feed water softening. solids.
the multi-effect
tube evaporation
of feed water pretreatment
with treated
initial
utilizing
increase
under design conditions
vessels
a smaller
drop in the evaporating
gave a significant
of Calcium
Furthermore
to the feed water results
materials.
obtained
5-fold. This condosing and pretreat-
hence the overall
(ref. 2, 3, 4, 5). Effects and feed heaters
fer coefficients
for
of 135 'C. These facts and the
with vertical
and tube side pressure
tube geometry
supply for
time.
temperature
is no need for inter-effect
fluted
brine
was concentrated
the number of effects
tendency
with advanced rates
operating
energy
power consumption
in costs for chemical
an evaporator
of foamy upflow combined
to increase
electrical
volumes and pump sizes.
start-up
realized
is based on the
the thermal
on the barge.
the evaporator
a reduction
reduces
The MEOA project
application
utilized
as well as vessel
inventory
fuel consumption
This incorporates
in the regenerating
one hour. After until the residual brine reached
the
operation of the ion exchanger system resulted in 2+ 2+ and 70 % Mg . Calcium content in the treat-
of more than 90 % Ca
ed feed was measured
by atomic
sorption
that such systems
can be applied
brine temperature
of 135 "C and above.
in the on board laboratory.
for operating
without
acid-dosing
This shows at a maximum
CONCLUSIONS The practical
feasibility
of advanced
desalting
technology
as presented
on a full-scale
production
size plant. This
has been successfully
demonstrated
has also demonstrated
that performance
process are achievable.
ratios 2 to 3 times higher
This will result
in considerable
benefit,
here
than MSF in that over-
44 all costs on large scale desalination successful VTFE
demonstration
plants can be substantially
of MEDA at Helgoland
or VTFE for single and dual purpose
supports
reduced.
the acceptance
The
of VC/
plants.
ACKNOWLEDGEklENTS The authors generous
and Incon Anlagentechnik
financial
support
(BMFT) of the Federal
Republic
ment. They are also indebted seewerke
GmbH, without
ions to the execution
GmbH, acknowledge
of the Ministry
for Research
with gratitude
of Germany as well as their continuous
to Incon's Joint Venture
whose active
involvement,
the
and Technology
partner,
Thyssen
from inception,
encourageNord-
and contribut-
of the work, the MEDA project may not have been realized.
REFERENCES
1 2 3 4 5
D.K. Emmermann, An advanced barge mounted VTE/VC for the desalination of seawater,'International Congress on Desalination and Water Re-Use, Bahrain Nov. 29 - Dec. 3, 1981 E. Kirschbaum et al: WarmeUbergang im senkrechten Verdampferrohr, VDI Forschungsheft 375, 193-i. E. Kirschbaum, Der WarmeUbergang im senkrechten Verdampferrohr, Chem. Ing. Techn. Nr. 1, 1954 E. Kirschbaum, Der WPrmeUbergang im senkrechten Verdampferrohr, Chem. Ing. Techn. Nr. 5, 1955 H.H. Sephton, Development of vertical tube foam evaporator for desalination, OWRT report - PB-248 667, June 1975
Fig. 1. Barge-mounted VC/VTFE seawater capacity of 5000 m'/day fresh water.
Fig. 2. Plant operation
is remotely
desalination
controlled
plant MEDA with a nominal
from this central
room.
HP-steam from boiler
Feed water
pretreatment
f---------1
I
t
loo-qf~12 6
Vapor compression
I
I
I
I---J
cycle
I
1
I
I
I
I r--I
1 I
I I
I I
7
:
'31
MSF -
16 .
evaporator
1 Seawater intake 2 Reject condenser 3 Cooling water discharge L Ion exchanger 5 Decarbonator
system
7 Feed water pump 0 Feed water to topping effect 1 9 Vapor compression effect Is.1 10 Compressor 11 Turbine I Generator
3.
Process
12 HP-steam by-pass 13 LP-steam to 19 VTFE-effect IL Distillate out off V&nit 15 Brine to 1st VTFE-effect 16 Distillate to MSF-unit 17 Brine to MSF-unit
6 Deaerator
Fig.
17
diagram
18 Non-condcnsiblcs
from VTFE-unit
19 Blow down 20 Product water 21 Vacuum pump 22 Steam condensate
pump
2 i
_II-w
Loo0
v 2000 5 r c1 z 1000
*
.
% I” 0
Fig.4
1
“‘.’ 1 2
3
1
5
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 No. of feed heoter
tubes based on outside
range 45 - 135 "C, average
Fig.5.
8
. Overall heat transfer coefficients
with double-fluted
z ii
7
6
0
',.""."""."'.",.' 1 2 3 L 5 6 7
Overall
on outside
velocity
heat transfer
tube diameter
loading 4 l/min/tube,
0
for vertically tube diameter
oriented
feed heater
of 19 mn. Temperature
1.5 m/s, tube wall thickness
0.9 mm.
9 IO ll 12 13 IL 15 16 17 18 19 20 21 22 23 2.L Na of VTFE -Effect
coefficients
for vertical
of 50 mm. Temperature
10 ppm surfactant,
tube foamy upflow
range 50 - 130 "C, average
tube wall thickness
0.9 mn.
based liquid