-
CORROSION CONTROL OF ABOVE GROUND STORAGE TANK BOTTOM STEEL
PLATES USING ALUMINUM MESH ANODE WITH NEWLY DEVELOPED
BACKFILL
Miki Funahashi, PE
MUI International Co. LLC
www.mui-int.com
ABSTRACT
Above-ground storage tank bottoms are subject to corrosion. The
tank bottoms have been protected
from corrosion by several methods, including oil sand, asphalt
sand or impressed current cathodic
protection. The insulating property of the oil and asphalt
supposes to stop corrosion; however, the
effectiveness of this approach has been questioned due to
corrosion failure resulting from insufficient
dielectric protection. Impressed current CP electrochemically
stops the corrosion on the tank plates
in contact with sand or soil underneath. However, it cannot
protect the plate once it loses the contact
with the soil. In addition, if the transformer rectifier or the
system hardware fails, the cathodic
protection is not effective until it repairs or replaced.
A new sacrificial anode system was developed using aluminum mesh
with a high pH modified sand
backfill to overcome the problems raised by the other corrosion
control systems. This paper will
discuss the new sacrificial anode CP system.
Key words: above-ground storage tank, sacrificial anode,
cathodic protection, aluminum mesh anode,
passive film, backfill material, high pH,
INTRODUCTION
The bottom plates of above-ground storage tanks are subject to
corrosion. In some situations, the tank
bottom may be protected from corrosion by oil sand, asphalt sand
or impressed current cathodic
protection. The protection by oil or asphalt sand takes
advantage of the dielectric, non-electrolytic
property of the oil and asphalt. Recently, however, it was
verbally reported in Japan the effectiveness
of this approach has been questioned due to corrosion failure
resulting from insufficient dielectric
protection. In addition, water or rain intrusion from the edge
of the tank bottom plate may accelerate
-
corrosion in those areas.
Impressed current cathodic protection generally uses an inert
anode with a transformer rectifier. The
anode is typically embedded in sand or soil. The cathodic
protection current from the anode travels
through the sand or soil electrolyte which contacts the steel
plate and protects the tank plate from
corrosion. So long as the tank plate contacts the sand/soil
electrolyte, the impressed current cathodic
protection is effective.
However, when the volume of the product inside the tank decrease
or is emptied, the tank plate rises
from the sand or soil, resulting in development of air gaps in
some areas. If this occurs, the cathodic
protection current cannot reach the tank steel surface located
over the air gaps because the air cannot
transfer the cathodic protection current (Figures 1 and 2). As a
result, the effectiveness of the
corrosion protection using an impressed current is lost, and
those areas are subject to corrosion.
In addition, since cathodic protection is continuously operating
system, interruption or malfunction of
the transformer rectifier or damage of any cathodic protection
hardware stops the protection of the
steel plate from corrosion.
Sacrificial anode cathodic protection systems using zinc plates
embedded in a conventional
bentonite/gypsum backfill have been used to protect the tank
plates in Japan. However, the
disadvantages of this system are:
When the zinc plates are embedded in the conventional calcium
bentonite and gypsum based backfill,
the passivation of the zinc can be minimized. However, since the
tank steel plate is also in contact
with the backfill, it is now exposed to a highly corrosive
electrolyte. Therefore, the steel is subject to
corrosion when the current from the zinc anode plates
decrease.
Aluminum or aluminum alloys are generally used in seawater or
brackish water as a sacrificial anode
because the high chloride concentration prevents the passivation
of the aluminum. The aluminum
anode has a high electrical capacity and high utilization
factor. In sand or soil environment, however,
aluminum or aluminum alloy does not function as a sacrificial
anode due to the passivation. Even if
an aluminum anode is embedded in the backfill material
containing a high chloride concentration, the
chloride ions diffuse into the surrounding soil in a short
period of time because of the highly mobile
tendency of chloride ions. Therefore, the aluminum or aluminum
alloys cannot function as a cathodic
protection anode in earth burial conditions.
To overcome these concerns and problems, a new sacrificial anode
system was developed using
aluminum mesh in conjunction with specially modified pH buffered
backfill sand. The proposed
aluminum mesh is Alloy 1100 and the typical chemical composition
can be found in Table 1
-
ALUMINUM MESH SACRIFICIAL ANODE
USING HIGH pH MODIFIED SAND BACKFILL
When aluminum or aluminum alloys are embedded in a high pH
electrolyte, the formation of the
passive film on the aluminum can be prevented as indicated in
Figure 3. This allows these metals to
function as cathodic protection anodes. Another advantage is
that the aluminum oxide products
formed on the anode is highly soluble, so that the aluminum
oxides do not adhere to the anode
surface.
When both steel and pure aluminum (anode) are exposed in the
same high pH electrolyte
environment and electrically connected, the following benefits
are accrued:
1. The passivation of aluminum can be prevented.
2. Cathodic protection current requirements are reduced
significantly.
3. The consumption rate of the aluminum anode is reduced,
increasing its life expectancy.
4. Cathodic reactions occurring on the steel create a more
durable passive film over time
5. Due to the strong passive film, the steel still protects for
an extended period of time when
cathodic protection is removed.
The benefit from higher pH backfill is also described by
American Petroleum Institute (API),
Recommended Practice 651 Cathodic Protection of Aboveground
Petroleum Storage Tanks.1
When steel is in contact with a high pH electrolyte (preferably
10 or greater), the steel passivates and
develop a stable protection film on its surface, resulting in no
corrosion until the film is disrupted.
Furthermore, when cathodic protection is applied to the steel
plate, sufficient hydroxyl ions (OH-)
develop on the steel surface as the cathodic reaction products.
As a result, the steel plate further
passivates. Once the strong and thick passive film is formed on
the steel surface, the protection film is
maintained for some time even if the tank plate losses contact
with the soil or sand underneath
(Figures 4 and 5 ). A typical example of passive steel in a high
pH electrolyte is the reinforcing steel
in chloride free concrete.
When steel is embedded in a neutral pH soil or sand electrolyte,
typically 10 to 20 mA/m2 of cathodic
protection current density is required to control corrosion. On
the other hand, to protect the steel in a
high pH electrolyte using cathodic protection, only 0.2 to 2
mA/m2 is required to control corrosion.
2
This lower cathodic protection current requirement significantly
reduces sacrificial anode
requirements.
By utilizing these advantages, a new sacrificial anode cathodic
protection system was developed
-
using aluminum mesh with special buffered high pH buffered
modified and a special backfill material.
The reasons to select the aluminum mesh are:
1. The wide expanded mesh can be installed under the steel tank
bottom plate in order to distribute
the cathodic protection current uniformly.
2. The mesh form reduces the amount of aluminum required. This
reduces the cost of the anode.
3. The mesh assures a large anode surface area in contact with
the backfill. This lowers
anode-to-electrolyte resistance and assure uniform consumption
of the anode.
The new sacrificial anode system has the following advantages
over other systems:
1. The capability to use sacrificial aluminum anode for steel
plates for cathodic protection of
above-ground storage tanks for extended period of time.
2. The mesh form of the sacrificial anode provides uniform
corrosion control to the entire tank
plate.
3. A small amount of the sacrificial anode is required to
protect the steel plate due to the low current
demand of the passivated steel plate.
4. Prevention of corrosion can be achieved in areas over air
gaps.
To achieve the items discussed above, a new sacrificial aluminum
mesh sacrificial anode with
specially modified pH buffered sand backfill was developed,
which have the following properties:
1. It maintains high pH as a buffer backfill material for a long
period of time.
2. It holds reasonable amount of moisture for a long period of
time to make the sacrificial anode
active.
3. It is stable during the welding process of the steel tank
bottom plates during construction.
EXPERIMENT
Two types of backfill materials and commercially available
aluminum mesh (Alloy 1100) were
prepared:
Backfill A: Moist Sand (as control), consists of sand and
Zeolite. The pH of this backfill was
approximately 7. The water content is approximately 18
percent.
Backfill B: High pH modified sand, consists of sand, Zeolite,
alkaline buffer chemicals and a
stabilizer. The pH of this backfill is 11. The water content is
also 18 percent.
Approximately 100 mm thick regular sand was laid on the bottom
of two plastic containers (approx 1
-
m L x 0.5 m W x 0.7 m D) as shown in Figure 6. Backfills A and B
were placed in separated
containers containing an aluminum mesh anode. The height of each
backfill material was
approximately 100 mm, and the aluminum mesh (0.22 m x 0.22 m x 4
mm, 55 gram) was positioned
at the mid depth of the backfill after they were weighted
(Figure 7).
Two steel plates (0.28 m x 0.14 m x 2 mm each) were laid on the
top of the backfill and welded each
other (Figure 8). The steel surface area in contact with the
backfill was 0.0784 m2. The steel plate and
the aluminum mesh were connected through a 0.1 ohm shunt
resistor and a switch to measure the
current output and instant-off potentials. The potentials were
measured using a portable
copper/copper sulfate reference electrode.
The plastic containers containing Backfills A and B were
covered, and the effectiveness of the
cathodic protection was monitored for 329 days using the 100 mV
Depolarization Criterion. The 100
mV Depolarization Criterion is only applicable to this condition
due to the high pH. (Figure 9)
After the test, the steel plates and the aluminum mesh were
removed from the backfill material and
left in a plastic container for about one month. The containers
were stored at approximately 30C with
a relative humidity greater than 90%. The steel plates and the
aluminum meshes were removed for
visual inspection at the end of one month.
To determine the aluminum mesh electrochemical capacity,
electrochemical testing was performed
using an impressed current of 1 mA/cm2. The schematic test set
up is shown in Figure 10 and is
similar to ASTMG97 (Test Method for Laboratory Evaluation of
Magnesium Sacrificial Anode
Specimens for Undergrounds Applications). The test was conducted
in the high pH modified sand
with 18 percent of moisture content.
A piece of the pure aluminum mesh containing 3 grids (7 cm x 3cm
opening) was used for this testing.
The surface area was approximately 30 cm2 and the initial weight
was 8.516 grams. After the
exposure test of 240 hours, the aluminum mesh was removed from
the sand for the weight loss
measurement.
RESULTS
Tables 2 to 4 show the data collected during the 329 days test
period, and Figures 11 and 12 show the
performance of the sacrificial anode system,
The results are summarized as follows.
Backfill A
-
Table 2 shows that the steel plate on Backfill A was never
cathodically protected by the aluminum
anode using either the 100 mV depolarization or the -850 mV
criterion. The initial current density
was 3 mA/m2 but dropped to a much lower current density in
approximately 60 days.
The static potential of the aluminum plate indicated that it
passivated after 60 days of the test period.
(Table 3) The aluminum mesh did not show any corrosion stains,
and the surface was completely
smooth, indicating the passivation of the aluminum mesh (Figure
11).
The static potential of the steel plate indicated that it did
not passivate (Table 4). The steel plate
showed significant corrosion as evidenced by brown rust stains
on the entire surface (Figure 12).
The pH on the steel and the aluminum mesh surfaces were
approximately 6 and 8, respectively. The
pH at the aluminum-backfill interface coincided with the passive
potential of the aluminum.
Backfill B
Backfill B enhanced the aluminum anode activity, and the
aluminum plate cathodically protected the
steel plates based on the 100 mV depolarization criterion (Table
2). The criterion was readily
achieved by initial current density of 1 mA/m2 which fell to 0.2
mA/m
2 after 84 days.
The static potentials of the aluminum plate indicated that it
did not passivate in the backfill. (Table 3)
The aluminum mesh showed corrosion stains on the entire surface.
Small corrosion pits were also
detected. The material loss due to corrosion was negligible.
(Figure 13)
The static potential of the steel plate indicated passivation
within 3 days from the start of testing. The
steel plated showed a uniform black passive film on the entire
surface. The surface was completely
smooth. No corrosion loss or rust stains were observed (Figure
14).
The pH on the steel and the aluminum plate surfaces were
approximately 12 and 11, respectively.
These potentials coincided with the conditions of the aluminum
and the steel plate in the backfill.
The steel condition exposed to air for one month indicated that
the steel plate over moist sand showed
further corrosion (Figure 15), but there was no evidence of
corrosion on the steel plate which had
been in contact with Backfill B (Figure 16).
Determination of the aluminum mesh life
After the specimen was exposed to 1 mA/cm2 (10 A/m
2) for 240 hours, the weight loss was 4.92
-
grams, The anode capacity of the aluminum mesh was calculated by
the following equation:
Anode Capacity (Amp-Hr/kg) = Total current (Amp-Hr)/ Weight Loss
(kg)
The total current used for 10 days was 7.2 Amp-hr and the weight
loss was 4.92 grams. Therefore,
the electrical capacity of this aluminum mesh was approximately
1,463 A-hr/kg. It is assumed that the
average current density for the steel plate to protect is 0.3
mA/m2 or 0.0003 A/m
2 because this current
density met the 100 mV Depolarization Criterion for the steel
plate with this backfill.
1,463 A-hr/kg / 0.0003A/m2 = 4,878,049 Hr-m
2/kg
557 year-m2/kg
Since the aluminum mesh used with Backfill B was 1.157 kg/m2,
the anode life is
557 year/kg-m2 x 1.157 kg/m2 = 644 years
This assumed that the backfill is stable, and corrosion is
uniform overtime with 100% utilization. 30
years is a typical cathodic protection design life for an above
ground storage tank bottom. Therefore,
a significantly lighter aluminum mesh, such as 0.1 kg/m2 should
be sufficient for 30 years life.
CONCLUSIONS
1. Exploiting the electrochemical characteristics of aluminum or
its alloys in a high pH electrolyte,
as well as the electrochemical characteristics of steel in a
high pH electrolyte, the commercially
available aluminum mesh in the high pH modified sand backfill
provides cathodic protection
system for the tank bottom steel plates.
2. After 329 days of cathodic protection application, the steel
plate was completely passivated and
showed protection passive film on the steel surface.
3. The high pH modified sand significantly reduced the cathodic
protection current requirement for
the steel plate with time.
4. This passive film on the steel plate was maintained in air
for a one month period at approximately
30 C and in 90% relative humidity without cathodic protection.
This indicates that this system
can continuously provide corrosion protection to the tank plate
over air gaps for at least one
month.
REFERENCES
-
1. API Recommended Practice 651, Third Edition, Cathodic
Protection of Aboveground Petroleum
Storage Tanks, January 2007
2. European Standard, Cathodic Protection of Steel in Concrete,
EN12969, March, 2000.
Table 1. Alloy 1100 Chemical Composition
Element Percent (%)
Aluminum 99.00 min.
Copper 0.05-0.20
Silicon + Iron 0.95 max.
Manganese 0.05 max.
Zinc 0.10 max.
Others, Each 0.05 max.
Others, Total 0.15 max.
Table 2. Results of Cathodic Protection.
Test duration
(days)
Backfill A Backfill B
Cathodic
protection
current density
(mA/m2)
Amount of
depolarization
(mV)
Cathodic
protection
current density
(mA/m2)
Amount of
depolarization
(mV)
14 3 33 1 165
26 1.63 27 0.88 168
61 0.6 10 0.75 124
84 0.4 4 0.2 132
96 0.35 8 0.35 154
180 0.22 32 0.2 130
270 0.12 12 0.23 125
329 0.08 7 0.19 129
-
Table 3. Static Potentials of the Aluminum Anodes
Test Duration
(days)
Static Potential of Aluminum
Mesh in Backfill A
Static Potential of Aluminum
Mesh in Backfill B
14 -974 -1485
26 -833 -1115
61 -655 -1127
84 -506 -1109
96 -457 -1120
180 -450 -947
270 -410 -923
329 -339 -942
Table 4. Static Potential of the Steel Plates
Test Duration
(days)
Static Potential of Steel Plate
in Backfill A
Static Potential of Steel
Plate in Backfill B
14 -730 -319
26 -687 -213
61 -630 -209
84 -586 -216
96 -566 -228
180 -448 -199
270 -441 -187
329 -411 -173
Figure 1. Ideal Condition for Cathodic Protection Figure 2.
Steel Plate Over Air Gaps Cannot be for Steel Plate Protected by
CP
-
0 2 4 6 8 10 12 14pH
Corr
osi
on
Rate
of
Al
(mg/d
m2/h
r)
0
1
4
6
8
10
2
3
5
7
9
Figure 3. Aluminum Corrosion Condition in Variuos pH
Environments From Shatalov, Dokl. Akad. Nauk, 86, 775 (1952),
as reproduced by Deltombe and Puorbaix, Corrosion,
14, 498 (1958) and
New Backfill
Figure 4. Cathodic Protection Current Distribution Figure 5.
Steel Plate Passivates and is Protected Over Air Gaps
Figure 6. Shows Regular Sand Before Install New Figure 7.
Aluminum Mesh Being Weighted Before Sacrificial Anode System
Installation
-
Figure 8. After Steel Plates Positioned Figure 9. Experiment
Conditions on New Sacrificial CP System
A
+-
DC Power Supply
Aluminum
Mesh
New Backfill
Steel Can
Figure 10. Weight Loss Test to Determine the Aluminum Mesh
Electrical Capacity
-
Figure 11. No Sigh of Corrosion on Aluminum Figure 12. Shows
Sever Corrosion of Steel Mesh in Backfill A on Backfill A
Figure 13. Shows Corrosion on Aluminum Figure14. Shows No
Corrosion on Mesh in Backfill B Steel Plate in Backfill B
Figure 15. Shows Further Corrosion After One Month Figure 16.
Shows No Corrosion of Steel Plate without CP (Backfill A) after One
Month Without CP
(Backfill B)
