ASTM D6442-06(2012)
(Test Method)Standard Test Method for Determination of Copper Release Rate From Antifouling Coatings in Substitute Ocean Water
Standard Test Method for Determination of Copper Release Rate From Antifouling Coatings in Substitute Ocean Water
SIGNIFICANCE AND USE
4.1 This test method is designed to provide a laboratory procedure to quantify and characterize the release rates of copper from antifouling coatings in substitute ocean water over a period of immersion under specified laboratory conditions of constant temperature, pH, salinity, and low copper concentration. Quantitative measurement of the release rate is necessary to help in selection of materials, in providing quality control, and in understanding the performance mechanism.
4.2 Results from this test method establish a pattern of copper release from an antifouling coating over a minimum of 45 days exposure under controlled laboratory conditions. Copper release rates from antifouling paints in-service vary over the life of the coating system depending on the formulation and on the physical and chemical properties of the environment. Factors such as differences in berthing locations, operating schedules, length of service, condition of paint film surface, temperature, pH, and salinity influence the actual release rate under environmental conditions. Results obtained using this test method do not reflect actual copper release rates that will occur in-service, but provide comparisons of the release rate of different antifouling formulations in substitute ocean water under the prescribed laboratory conditions.
4.3 By comparison with copper release rate measurements obtained either by direct measurements of copper release rate from AF coating systems on ship hulls, or copper release rate measurements from AF coating systems from harbor exposed panels, all available data indicate that the results of this test method (Test Method D6442) significantly overestimate the release rate of copper when compared to release rates under in-service conditions. Published results demonstrate that this test method produces higher measurements of copper release rate than from direct in-situ measurements for the same coating on in-service ship hulls and harbor-exposed panels. The di...
SCOPE
1.1 This test method covers the laboratory determination of the rate at which copper is released from an antifouling (AF) coating in substitute ocean water. The practical limits for quantifying copper release rates by this method are from 1.8 to 500 μg cm-2d-1. This range may be extended to 0.2 to 500 μg cm-2d-1 if the analytical procedure described in Appendix X1 is followed.Note 1—The term “substitute ocean water” is used throughout this standard to refer to artificial or synthetic seawater prepared in accordance with Practice D1141.
1.2 The procedure contains the preparation steps for the release rate determination of copper from antifouling paints including apparatus, reagents, holding tank conditions, and sampling point details. Analysis for the concentration of copper in substitute ocean water requires the accurate determination of copper at the low parts μg L-1 (parts per billion, ppb) level. To detect and correct for reagent impurities, acceptable analytical precision standards are necessary. Therefore, the limit of quantitation (LOQ) for copper in substitute ocean water for the analytical method shall be 10 μg L-1 (10 ppb) or less. The procedure for determining the LOQ for copper in substitute ocean water for the analytical method is found in Annex A2.
1.3 A suitable method is described in Appendix X1 (graphite furnace atomic absorption spectroscopy, GF-AAS). Other analytical methods may be utilized with relevant procedural changes, as needed, to accommodate selected specific methods. Such methods must meet the limit of quantitation for copper in substitute ocean water of 10 μg L-1 (10 ppb) or less. See 1.2.
1.4 This results of this test method do not reflect environmental copper release rates for antifouling products, and are not suitable for direct use in the process of generating environmental risk assessments, environmental loading estimates, or for establishing release rate limits for regulatory p...
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Designation: D6442 − 06 (Reapproved 2012)
Standard Test Method for
Determination of Copper Release Rate From Antifouling
Coatings in Substitute Ocean Water
This standard is issued under the fixed designation D6442; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
1. Scope* 1.5 The values stated in SI units are to be regarded as the
standard. The values given in parentheses are for information
1.1 This test method covers the laboratory determination of
only.
the rate at which copper is released from an antifouling (AF)
1.6 This standard does not purport to address all of the
coating in substitute ocean water. The practical limits for
safety concerns, if any, associated with its use. It is the
quantifying copper release rates by this method are from 1.8 to
-2 -1
responsibility of the user of this standard to establish appro-
500 µg cm d . This range may be extended to 0.2 to 500 µg
-2 -1
priate safety practices and to determine the applicability of
cm d iftheanalyticalproceduredescribedinAppendixX1is
regulatory limits prior to use. For specific hazard statements,
followed.
see Section 7.
NOTE 1—The term “substitute ocean water” is used throughout this
standard to refer to artificial or synthetic seawater prepared in accordance
2. Referenced Documents
with Practice D1141.
2.1 ASTM Standards:
1.2 The procedure contains the preparation steps for the
D1005 Test Method for Measurement of Dry-Film Thick-
release rate determination of copper from antifouling paints
ness of Organic Coatings Using Micrometers
including apparatus, reagents, holding tank conditions, and
D1141 Practice for the Preparation of Substitute Ocean
samplingpointdetails.Analysisfortheconcentrationofcopper
Water
insubstituteoceanwaterrequirestheaccuratedeterminationof
-1
D1193 Specification for Reagent Water
copper at the low parts µg L (parts per billion, ppb) level. To
detect and correct for reagent impurities, acceptable analytical
3. Summary of Test Method
precision standards are necessary. Therefore, the limit of
3.1 The candidate paint is applied to cylindrical test speci-
quantitation (LOQ) for copper in substitute ocean water for the
-1
mens. The coated specimens are placed in a tank of substitute
analytical method shall be 10 µg L (10 ppb) or less. The
-1
ocean water where the copper levels are kept below 100 µg L
procedure for determining the LOQ for copper in substitute
by circulating the substitute ocean water through a suitable
ocean water for the analytical method is found in Annex A2.
filtration system (see 5.3). At specified intervals, each speci-
1.3 Asuitable method is described in Appendix X1 (graph-
men is placed in 1500 mL of substitute ocean water (see
ite furnace atomic absorption spectroscopy, GF-AAS). Other
Section 9 for details) and rotated at 60 revolutions per minute
analytical methods may be utilized with relevant procedural
(rpm) for 1 h (or less, see 9.8 for further explanation and
changes,asneeded,toaccommodateselectedspecificmethods.
instruction). The rate of copper release from the paint is
Such methods must meet the limit of quantitation for copper in
determined by measuring copper concentrations of the substi-
-1
substitute ocean water of 10 µg L (10 ppb) or less. See 1.2.
tute ocean water in the individual measuring containers.
1.4 This results of this test method do not reflect environ-
3.2 Appendix X1 provides an analytical procedure for
mental copper release rates for antifouling products, and are
measuring copper concentrations in substitute ocean water.
not suitable for direct use in the process of generating
environmental risk assessments, environmental loading
4. Significance and Use
estimates, or for establishing release rate limits for regulatory
4.1 This test method is designed to provide a laboratory
purposes. See also Section 4 on Significance and Use.
procedure to quantify and characterize the release rates of
copperfromantifoulingcoatingsinsubstituteoceanwaterover
This test method is under the jurisdiction of ASTM Committee D01 on Paint
and Related Coatings, Materials, andApplications and is the direct responsibility of
Subcommittee D01.45 on Marine Coatings. For referenced ASTM standards, visit the ASTM website, www.astm.org, or
Current edition approved June 1, 2012. Published August 2012. Originally contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
approved in 1999. Last previous edition approved in 2006 as D6442 – 06. DOI: Standards volume information, refer to the standard’s Document Summary page on
10.1520/D6442-06R12. the ASTM website.
*A Summary of Changes section appears at the end of this standard
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
D6442 − 06 (2012)
a period of immersion under specified laboratory conditions of diameter to serve as baffles. Rods shall be evenly spaced on the
constant temperature, pH, salinity, and low copper concentra- inside circumference of the container to prevent swirling of the
tion. Quantitative measurement of the release rate is necessary water with the test cylinder during rotation. The rods will be
to help in selection of materials, in providing quality control, secured to the container walls using acetone or methylene
and in understanding the performance mechanism. chloride (see Annex A1).
4.2 Results from this test method establish a pattern of 5.2 Constant Temperature Control—A means of maintain-
copper release from an antifouling coating over a minimum of ing the release rate measuring test containers at a temperature
45 days exposure under controlled laboratory conditions. of 25 6 1°C during the rotation period (see 9.8).
Copper release rates from antifouling paints in-service vary
5.3 Holding Tank—Aninertplasticcontainerofsuchdimen-
over the life of the coating system depending on the formula-
sions so as to permit immersion of four or more test cylinders;
tion and on the physical and chemical properties of the
must be equipped with a system to continuously circulate the
environment. Factors such as differences in berthing locations,
substitute ocean water in the tank through an activated carbon
operating schedules, length of service, condition of paint film 5
filter and optionally an absorbent filter. If an absorbent filter is
surface, temperature, pH, and salinity influence the actual
used, regenerate the ion-exchange resin following the manu-
release rate under environmental conditions. Results obtained
facturer’s instructions and wash the resin with substitute ocean
using this test method do not reflect actual copper release rates
water prior to use. The rate of water flow and the size of the
that will occur in-service, but provide comparisons of the
filter(s) shall be selected to maintain copper concentrations
release rate of different antifouling formulations in substitute -1
below 100 µg L . Flow rates should be set to obtain 2 to 8
ocean water under the prescribed laboratory conditions.
turnovers per hour.
4.3 By comparison with copper release rate measurements
5.4 The size and geometry of the tanks as well as the
obtained either by direct measurements of copper release rate
positioning of the inflow and outflow ports for the water
from AF coating systems on ship hulls, or copper release rate
circulation system shall be selected to obtain a slow, relatively
measurements from AF coating systems from harbor exposed
uniform flow of substitute ocean water past all test cylinders in
panels, all available data indicate that the results of this test
the tank. Maintain the pH of the substitute ocean water
method (Test Method D6442) significantly overestimate the
between 7.9 and 8.1, the salinity between 33 and 34 parts per
release rate of copper when compared to release rates under
thousand (ppt), and temperature at 25 6 1°C (77 6 2°F).
in-service conditions. Published results demonstrate that this
5.5 Test Cylinders—Approximately 6.4 cm (nominal 2 ⁄2
test method produces higher measurements of copper release
in.) outside diameter by 17.8 cm (nominal 7 in.) long polycar-
ratethanfromdirectin-situmeasurementsforthesamecoating
bonate pipe or equivalent polycarbonate cylindrical shapes
on in-service ship hulls and harbor-exposed panels. The
coated with a 10 cm (3.94 in.) band of antifouling paint around
difference between the results of this test method and the panel
the exterior circumference of the test cylinder to provide 200
and ship studies was up to a factor of about 30 based on data
3,4
cm ofpaintfilmthatcanbeimmersedandfreelyrotatedinthe
for several commercial antifouling coatings. Realistic esti-
release rate measuring container (see Note 2).Atop disc, fitted
mates of the copper release from a ship’s hull under in-service
with a shaft of proper diameter for the rotating device, should
conditions can only be obtained from this test method where
be sealed to the cylinder. Seal the bottom of the test cylinder
the difference between the results obtained by this test method
with a polycarbonate disc using acetone, methylene chloride or
and the release rate from anAF coating in-service is taken into
a polycarbonate cement so as to form a watertight joint. Do not
account.
coat the lower 1 to 2 cm (0.39 to 0.79 in.) of the test cylinder.
4.4 Where the results of this test method are used in the
The test cylinder shall be of such height so that a rotating
process of generating environmental risk assessments, for
device can be attached to rotate the cylinder with the upper end
environmental loading estimates, or for regulatory purposes, it
of the cylinder above the level of the test container immersion
is most strongly recommended that the relationship between
liquid to prevent entry of the immersion liquid into the test
laboratory release rates and actual environment inputs is taken
cylinder (see AnnexA1). It is advisable to weight the cylinder
into account to allow a more accurate approximation of the
by filling with water so that the unit does not have buoyancy.
copper release rate from antifouling coatings under real-life
NOTE 2—When coating release rates are very high, it may be desirable
conditions. This can be accomplished through the application
2 -1
4 tousea5cm band (100 cm ) paint area to avoid exceeding 200 µg L of
of appropriate correction factors.
copper in the measuring containers (see 9.8.1).
5. Apparatus 5.6 Test Cylinder Rotating Device—The device shall be
capable of rotating the test cylinder in the release rate measur-
5.1 Release Rate Measuring Container—A nominal 2 L ( ⁄2
-1
ing container at 60 6 5 rpm (0.2 6 0.02 m·s , velocity of test
gal.) polycarbonate container, approximately 13.5 cm (5.3 in.)
cylinder surface). No part of the device shall be immersed in
in diameter and 19 cm (7.5 in.) high, fitted with three
substitute ocean water.
polycarbonate rods approximately 6 mm (nominal ⁄4 in.) in
3 5
Valkirs, A. O, Seligman, P. F., Haslbeck, E., and Caso, J. S., Marine Pollution A filter cartridge, containing a chelating iminodiacetic (alternative spelling –
Bulletin, Vol 46 (2003), pp 763–779. imminodiacetic) acid ion-exchange resin on a styrene support (nominal particle size
Finnie, A. A.,“Improved Estimates of Environmental Copper Release Rates range approximately 0.300 to 0.850 mm (20 to 50 mesh)) of sufficient capacity to
from Antifouling Products,” Biofouling, Vol. 22 (2006). In press. require regeneration only once a month or less frequently, has been found suitable.
D6442 − 06 (2012)
5.7 Sample Tubes—60 mL capacity with screw closures (or Additional spikes may be prepared at appropriate levels and
disposable bottles, culture tubes, etc.) made of polycarbonate, appropriate to the analytical technique being used.
polypropylene or borosilicate glass.
8.3 At the beginning of each instrument run, analyze a
5.8 Dispensers—Automatic or repeating for reagents.
suitable blank and standards in order to establish that the
response of the instrument is linear. Plot separate calibration
5.9 pH Meter, with a suitable electrode.
curves for each analysis of the standards (instrument response
5.10 Appropriate Hydrometer or Salinometer.
versus copper concentration) and calculate the slope, intercept,
5.11 Appropriate Volumetric Flasks.
and correlation coefficient for each curve using least squares fit
or another appropriate procedure.
5.12 Disposable Polypropylene Syringes, 60 mL.
8.4 Analyze the following:
5.13 Syringe Filters, 0.45 µm.
8.4.1 Substitute Ocean Water Blank: Acidify, extract and
6. Reagents and Materials
analyze as specified (see 9.10 and 9.11) for test samples, to
establish baseline.
6.1 Purity of Reagents—All reagents and cleaning agents
8.4.2 Spiked Substitute Ocean Water Samples: Acidify,
are to be reagent grade or better.
extract and analyze as specified (see 9.10 and 9.11) for the test
6.2 Purity of Water—Distilled water conforming to Type II
samples to determine extraction efficiency. Recovery must be
of Specification D1193.
-1
100 % 6 10 % for the 50 µg L spike and spikes of higher
6.3 Substitute Ocean Water—Artificial ocean water in ac-
concentration. Recovery must be 100 % 6 15 % for spikes
-1
cordance with Practice D1141, section on Preparation of
with a concentration below 50 µg L .
Substitute Ocean Water, or a proprietary equivalent with a
salinity of 33 to 34 ppt and pH 7.9 to 8.1.
9. Procedure
6.4 Extraction Media—Activated carbon and, optionally, a
9.1 Cleanpolycarbonatewarewithtapwaterthenrinsewith
chelating ion-exchange resin, iminodiacetic (imminodiacetic)
deionized water. All glass laboratory ware used for copper
acid exchange resin on a styrene support, nominal particle size
release rate measurements must be treated as follows: clean
range approximately 0.300 to 0.850 mm (20 to 50 mesh) (see
thoroughly by soaking in 10 % HCl for a minimum of 6 h.
5.3).
Cleaning can also be accomplished by soaking in concentrated
6.5 Copper Standards—Prepare standards using a stock
HCl for ⁄2 h. Rinse laboratory ware thoroughly with deionized
-1
solution of copper, 1000 mg L (1000 ppm), or other concen-
or distilled water and allow to dry. Prepare all samples, blanks
trationsuitabletotheselectedanalyticaltechnique(seeSection
and standards in laboratory ware treated in this manner.
8).
Disposable materials (pipettes, tips, centrifuge tubes, etc.) do
not have to be acid-washed before use.
6.6 Nitric Acid (HNO )—Concentrated, high purity grade.
9.2 Prepare the exposure surfaces of three replicate test
6.7 Hydrochloric
...
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