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ASTM F2084-01

(Guide)

Standard Guide for Collecting Containment Boom Performance Data in Controlled Environments

Standard Guide for Collecting Containment Boom Performance Data in Controlled Environments

SCOPE
1.1 This standard provides a guide for evaluating the effectiveness of full-scale oil spill containment booms in a controlled test facility.
1.2 This guide involves the use of specific test oils that may be considered hazardous materials. It is the responsibility of the user of this guide to procure and abide by the necessary permits for disposal of the used test oil.
1.3 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory requirements prior to use.

General Information

Status
Historical
Publication Date
09-Mar-2001
ICS
13.030.40 - Installations and equipment for waste disposal and treatment
Technical Committee
F20 - Hazardous Substances and Oil Spill Response
Drafting Committee
F20.11 - Control
Current Stage
Ref Project

Relations

Replaced By
ASTM F2084-01(2007)e1 - Standard Guide for Collecting Containment Boom Performance Data in Controlled Environments
Effective Date
01-Apr-2007

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ASTM F2084-01 - Standard Guide for Collecting Containment Boom Performance Data in Controlled Environments
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NOTICE: This standard has either been superseded and replaced by a new version or withdrawn.
Contact ASTM International (www.astm.org) for the latest information
Designation:F2084–01
Standard Guide for
Collecting Containment Boom Performance Data in
Controlled Environments
This standard is issued under the fixed designation F 2084; 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 (e) indicates an editorial change since the last revision or reapproval.
1. Scope D 4092 Test Method for Density and Relative Density of
liquids by Digital Density Meter
1.1 This standard provides a guide for evaluating the effec-
F 631 Guide for Collecting Skimmer Performance Data in
tiveness of full-scale oil spill containment booms in a con-
Controlled Environments
trolled test facility.
F 818 Terminology Relating to Spill Response Barriers
1.2 This guide involves the use of specific test oils that may
be considered hazardous materials. It is the responsibility of
3. Terminology
the user of this guide to procure and abide by the necessary
3.1 Boom Performance Data Terminology—Terms associ-
permits for disposal of the used test oil.
ated with boom performance tests conducted in controlled
1.3 This standard does not purport to address all of the
environments:
safety concerns, if any, associated with its use. It is the
3.1.1 boom submergence (aka submarining)—containment
responsibility of the user of this standard to establish appro-
failure due to loss of freeboard.
priate safety and health practices and determine the applica-
3.1.2 first-loss tow/current velocity—minimum tow/current
bility of regulatory requirements prior to use.
velocity normal to the membrane at which oil continually
2. Referenced Documents escapes past a boom This applies to the boom in the catenary
position.
2.1 ASTM Standards:
3.1.3 gross loss tow/current velocity—the minimum speed
D97 Test Method for Pour Point of Petroleum Oils
at which massive continual oil loss is observed escaping past
D 445 Test Method for Kinematic Viscosity of Transparent
the boom.
and Opaque Liquids (the Calculation of Dynamic Viscos-
3.1.4 harbor chop—a condition of the water surface pro-
ity)
duced by an irregular pattern of waves.
D 971 Test Method for Interfacial Tension of Oil Against
3.1.5 preload—during testing, the quantity of test fluid
Water by the Ring Method
distributed in front of and contained by the boom prior to the
D 1298 Practice for Density, Relative Density (Specific
onset of a test.
Gravity), or API Gravity of Crude Petroleum and Liquid
3.1.6 tow speed—the relative speed difference between a
Petroleum Products by Hydrometer Method
boom and the water in which the boom is floating. In this
D 1796 TestMethodforWaterandSedimentinFuelOilsby
standard guide relative current speed is equivalent.
the Centrifuge Method (Laboratory Procedure)
3.1.7 wave height—(significant wave height) the average
D 2983 Test Method for Low-Temperature Viscosity of
height, measured crest to trough, of the one-third highest
Automotive Fluid Lubricants Measured by Brookfield
waves, considering only short-period waves (i.e., period less
Viscometer
than 10 s).
D 4007 Test Method for Water and Sediment in Crude Oil
3.1.8 wave period—(significant wave period) the average
by Centrifuge Method (Laboratory Procedures)
period of the one-third highest waves, measured as the elapsed
time between crests of succeeding waves.
This guide is under the jurisdiction of ASTM Committee F20 on Hazardous
4. Significance and Use
Substances and Oil Spill Response and is the direct responsibility of Subcommittee
4.1 This guide defines a series of test methods to determine
F20.11 on Control.
Current edition approved Mar. 10, 2001. Published April 2001.
the oil containment effectiveness of containment booms when
For referenced ASTM standards, visit the ASTM website, www.astm.org, or
they are subjected to a variety of towing and wave conditions.
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
The test methods measure the tow speed at which the boom
Standards volume information, refer to the standard’s Document Summary page on
the ASTM website. first loses oil (both in calm water and in various wave
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
F2084–01
conditions), the tow speed at which the boom reaches a gross the manufacturer for both ends of the boom which provide
oil loss condition (both in calm water and in various wave attachmentpointsfortowing(Fig.1).Ateachendoftheboom,
conditions), boom conformance to the surface wave conditions the towing apparatus shall be joined to the tow bridle or tow
for various wave heights, wavelengths and frequencies, (quali- lead by a single point only. Boom towing force should be
tatively), resulting tow forces when encountering various measured with in-line load cells positioned between the boom
speeds and wave conditions, identifies towing ability at high towing bridles and tow points.
speeds in calm water and waves, boom sea-worthiness relative 7.2 Preload oil should be pumped directly into the boom
to its hardware (i.e., connectors, ballast members), and general apex.
durability. 7.3 Data obtained during each test should include electroni-
4.2 User’s of this guide are cautioned that the ratio of boom cally collected data and manually collected data. Oil and water
draft to tank depth can affect test results, in particular the tow propertydatashouldbebasedonfluidsamplesobtainedduring
loads (see Appendix X1 discussion). the test period. Recommended data to be collected during
4.3 Other variables such as ease of repair and deployment, testing, along with the method of collection, is listed in Table
required operator training, operator fatigue, and transportabil- 1.
ity also affect performance in an actual spill but are not
8. Test Fluids
measured in this guide. These variables should be considered
along with the test data when making comparisons or evalua- 8.1 Test fluids may be crude, refined, or simulated, but
tions of containment booms.
should be stable and have properties that do not vary during a
test run. Test oils for use with this guide should be selected to
fall within the range of typical oil properties as defined in
5. Summary of Guide
Appendix X2 of this guide.
5.1 This guide provides standardized procedures for evalu-
8.2 Test fluids should be discharged at ambient water
ating any boom system and provides an evaluation of a
temperatures to reduce variation in fluid properties through a
particular boom’s attributes in different environmental condi-
test run.
tionsandtheabilitytocomparetestresultsofaparticularboom
type with others having undergone these standard tests.
9. Safety Precautions
5.2 The maximum wave and tow speeds at which any boom
9.1 Test operation shall conform to established safety (and
can effectively gather and contain oil are known as boundary
regulatory) requirements for both test facility operations and
conditions. Booms that cannot maintain their design draft,
oil handling. Particular caution must be exercised when han-
freeboard, profile, and buoyancy at these conditions may be
dling flammable or toxic test fluids.
less effective. The boundary conditions depend on the charac-
teristics of oil viscosity, oil/water interfacial tension and
oil/water density gradient.
6. Test Facilities
6.1 Severaltypesoftestfacilitiescanbeusedtoconductthe
tests outlined in this guide:
6.1.1 Wave/Tow Tank—A wave/tow tank has a movable
bridge or other mechanism for towing the test device through
water for the length of the facility. A wave generator may be
installed on one end, or on the side of the facility, or both.
6.1.2 Current Tank—A current tank is a water-filled tank
equipped with a pump or other propulsion system for moving
the water through a test section where the test device is
mounted.Awavegeneratormaybeinstalledonthistypeoftest
facility.
6.1.3 Other facilities, such as private ponds or flumes, may
also be used, provided the test parameters can be suitably
controlled.
6.2 Ancillary systems for facilities include, but are not
limited to a distribution system for accurately delivering test
fluids to the water surface, skimming systems to assist in
cleaning the facility between tests, and adequate tankage for
storing the test fluids.
7. Test Configuration and Instrumentation
7.1 The boom should be rigged in a catenary configuration,
with the gap equal to 33 % of the length; or boom gap-to-
length ratio of 1:3. Towing bridles are generally provided by FIG. 1 Typical Boom Test Setup in Tank
F2084–01
TABLE 1 Typical Data Collected During Tests 1
10.3.2 Wave #1—sinusoidal wave with an H ⁄3 of .30 metres
Typical Collection (12.0 inches), wavelength of 4.27 metres (14.0 feet), and an
Data
Instrumentation Method
averageperiodoft=1.7seconds.(Wavedampeningbeachesare
Wind Speed, Wind Monitor Computer/Data Logger,
employed during the generation of this wave condition).
Direction Manual Readings
10.3.3 Wave #2—Sinusoidal wave with an H ⁄3 of .42 metres
Air and Water Resistance Temperature Computer/Data Logger,
(16.5 inches), wavelength of 12.8 metres (42.0 feet), and an
Temperature Detector (RTD), Manual Readings
Themocouples,
averageperiodoft=2.9seconds.(Wavedampeningbeachesare
Mercury Thermometer
employed during the generation of this wave condition).
Tow Pulse Counter and Computer, Control
10.3.4 Wave #3—A harbor chop condition with an average
Speed/Relative Digital Input Console, Local Display
Current Tachometer, Current
H ⁄3 of .38 metres (15.0 inches). This is also defined as a
Meter
confused sea condition where reflective waves are allowed to
Wave Data Distance Sensor, Computer/Data logger
Capacitance probe, develop. No wavelength is calculated for this condition.
Pressure Sensor
Tow Force, Load Cell Computer/Data logger
where:
Average
H ⁄3 = significantwaveheight = theaverageofthehighest ⁄3
(Maximum
of measured waves,
during Wave
Conditions)
L = wavelength = the distance on a sine wave from trough
Test Fluid Storage Tank Level Computer/Data Logger,
to trough (or peak to peak), and
(Volume Soundings, or Distance Manual Readings
T = wave period = the time it takes to travel one wave-
Distributed) Sensor and capacity vs.
Volume Conversions
length.
Distribution Rate Positive Displacement Pump Control Panel,
Pump with Speed Computer/Data Logger,
11. Procedures
Indicator, Volume Manual Readings
Distributed Divided by
11.1 Prior to the test, select the operating parameters, then
Time
prepare the facility and containment boom for the test run.
Measure the experimental conditions.
11.1.1 The conventional boom under test should be a
10. Test Variables
full-scale representative section. The boom section’s basic
10.1 At the onset of the test the independent or controlled physical properties should be measured in accordance with
test parameters should be selected. The test evaluator should ASTM definitions. Table 3 contains a list of typical measure-
include a discussion of the procedures that were used to
ments and additional specification data.
establish calibration and standardization. These procedures 11.2 Measure or note immediately prior to each test the
typically include initial calibrations, pre-test and post-test
following parameters:
checks, sampling requirements and documentation of signifi- 11.2.1 Wind speed, direction.
cant occurrences/variations, and data precision and accuracy.
11.2.2 Air and water temperature.
10.2 Data should be expressed with an indication of vari- 11.2.3 General weather conditions, for example, rain, over-
ability.Table2containsalistoftypicalmeasurementsshowing
cast, sunny, etc.
attainable precision and accuracy values. 11.2.4 Thetestfluidusedfortestingshouldbecharacterized
10.3 Varying surface conditions should be employed during
from samples taken each time the storage tank is filled. As a
testing. Conditions should be measurable and repeatable. minimum, the test fluid should be analyzed for viscosity,
Examples of achievable surface conditions in controlled test surface and interfacial tension, specific gravity and bottom
environments are:
10.3.1 Calm—No waves generated.
TABLE 3 Typical Basic Physical Properties
Specification Data
TABLE 2 Measurement Precision and Accuracy As reported by As measured by
Measurement
Manufacturer Tester
Measurement Accuracy (6) Precision (6)
Boom Type Fence, curtain, fire containment, other
Bottom solids and To be determined To be determined
Length m (ft) Standard section length, total rigged section
Water (ASTM) (ASTM)
Height mm (in) Standard section height
3 3
Oil Distribution 0.3 m /HR 0.05 m /HR
Freeboard mm (in) Distance above water line
0 0
Salinity .01 ⁄00 .01 ⁄00
Draft mm (in) Distance below water line
3 3
Specific Gravity, .001 g/cm 0.0001 g/cm
Weight of Section kg/m Boom Fabric Type (freeboard and skirt material)
Density
(lb/ft) and Tensile Strength Characteristics
Surface Tension 0.1 Dyne/cm 0.04 Dyne/cm
Ballast Bottom Tension Member Type/Break
Temperature 0.2°C 0.2°C Ballast Length m (ft)
A
Strength and Length
Tow, Current 0.051 m/se. (.1 kt)/ 0.0255 m/sec (.05kt)/
Ballast Weight kg/m (lb/ft) Chain, cable or weights
Speeds (Tank/Open 0.255 m/sec (.5 kt) 0.102 m/sec (.2 kt)
Gross Buoyancy Flotation/Buoyancy Type (Air inflatable/foam)
water)
Buoyancy to Weight Ratio Calculated/Measured (Method shall be documented)
Tow Force 0.25 % of full scale 2.5 lbs/1000 lbs
Accessories Anchor points, lights, tow lines, bridles, etc.
Viscosity 2.0 % 1.0 %
End Connector Type ASTM Standard, other
Wave Meter, 6 mm/10 mm 1.44 mm/10 mm
Number of tension
(Tank/Open Water)
Top, bottom, middle, other
members and Location
Wind Direction 3° 3°
A
Wind Speed 0.3 m/s (0.6 mph) 0.3 m/s (0.6 mph)
All measurements should be taken when member is tensioned to the load
expected at a 1 knot tow speed.
F2084–01
solids and water. The results of each analysis as presented in which improved or diminished containment performance can
Table 2 will be reported. be measured when encountering other test conditions.
11.2.5 Periodic samples of the test basin water should be
11.3.2.1 The preload volume is determined by performing a
taken to monitor the water properties to include oil and grease, series of first loss tests. Beginning with a nominal preload
salinity, pH, and turbidity.
volume, the first loss tow speed is identified. Underwater
11.3 Place the containment boom in the test basin (Fig. 1). visibility is essential when identifying loss speeds.The preload
Confirmthatrigginghasbeeninaccordancewithmanufacturer
volumeisincreasedandthefirstlosstowspeedobtainedagain.
specifications. Document set-up conditions, for example, tow
...

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ASTM
ASTM D7204-23(Practice)
Standard Practice for Sampling Waste Streams on Conveyors

SIGNIFICANCE AND USE
4.1 This practice can be used in sampling ash from a kiln or incinerator, soils, and process waste from conveying systems, such as a conveyer and vertical lifts. Some slurries, such as the bottom solids, can be sampled from the quench waters at the end of a kiln.  
4.2 This practice can be used to determine material balances for burner efficiency studies and compliance studies.  
4.3 This practice can be used on lifts, sloping, and horizontal conveyor systems. The type of conveyor and the amount and type of sample required will dictate the type of sampling equipment required to get a representative sample.  
4.4 The sample is taken directly from the conveyor before emptying into the waste container or pile for disposal or recycling using a scoop, dipper, or shovel depending upon the sample requirements (see Practice D5633). The sample is then put into the sample container for analysis.  
4.5 The place, quantity, frequency, and time of sampling is dependent upon the conveying system equipment, data quality objectives (DQOs) (Practice D5792), work or sampling plan (see Practice D5283 and Guide D4687), and analysis to be run.  
4.5.1 Large particles can be mechanically excluded on a belt system. Large particles may accumulate at the bottom of an inclined/sloped belt system. Therefore, steps, if possible, need to be taken so that particles of all sizes have equal chances of being sampled.  
4.5.2 The number of samples and sample time is dependent upon the system, the precision required, the decisions that are to be made, the cost, and the degree of heterogeneity of the material (see Guides D5956 and D6311).  
4.5.3 In general, the ideal sampling location is nearest to the point of generation since temperature, oxidation, and air movement may change some samples with time.  
4.6 The practice does not address issues related to the heterogeneity of the sample.
SCOPE
1.1 This practice describes standard procedures for sampling waste on open and closed conveying systems and is applicable to any waste material that can be conveyed to a waste pile or container. The conveyor system can be a vertical (vertical lifts), sloped, or horizontal type.  
1.2 This practice is intended for particles and slurries, which can be sampled using scoop, dipper, or shovel type samplers.  
1.3 The practice is not intended for large size sample constituents, such as boulders, large rocks, and debris.  
1.4 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.5 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM D5233-92(2023)(Test Method)
Standard Test Method for Single Batch Extraction Method for Wastes

SIGNIFICANCE AND USE
5.1 This test method is intended to generate an extract with a concentration of the target analyte(s) representative of the expected release under the scenario simulated, and which can be compared with concentration levels acceptable in waste disposal, treatment, or production activities.  
5.2 The extraction conditions of the test method were chosen to simulate a potential disposal scenario to which the wastes may be exposed.  
5.3 One intent of this test method is that the amount of acid in the extraction fluids reflects the acid available from the leachate of a specific landfill where municipal and industrial wastes were co-disposed.6  
5.4 One intent of this test method is to not allow the pH of the extraction fluid to be lower than that of the leachate of a specific landfill where municipal and industrial wastes were co-disposed. Therefore, the pH of the extraction fluid was chosen with the following considerations:
(1) Not to be less than 4.93 ± 0.05 for the extraction of wastes with an acid neutralization capacity of less than the acid available in the total volume of extraction fluid used in the method (Extraction Fluid No. 1).
(2) At 2.88 ± 0.05, as defined by the pH of the acid, for the extraction of wastes with an acid neutralization capacity of more than the acid available in the extraction fluid used in the method (Extraction Fluid No. 2).  
5.5 The interpretation and use of the results of this test method are limited by the assumptions of a single co-disposal scenario and by the factors affecting the composition of a landfill leachate and chemical or other differences between a selected extraction fluid and the real landfill leachate.  
5.6 This test method may be affected by biological changes in the waste, and it is not designed to isolate or measure the effect of such processes.  
5.7 This test method produces extracts that are amenable to the determination of both minor and major constituents. When minor constituents are being determined,...
SCOPE
1.1 This test method is applicable to the extraction of samples of treated or untreated solid wastes or sludges, or solidified waste samples, to provide an indication of the leaching potential.  
1.2 This test method is intended to provide an extract for measurement of the concentration of the analytes of concern. The measured values may be compared against set or chosen acceptance levels in some applications.  
1.3 If the sole application of the test method is such a pass/fail comparison and a total analysis of the waste demonstrates that individual analytes are not present in the waste, or that the chosen acceptance concentration levels could not possibly be exceeded, the test method need not be run.  
1.4 If the sole application of the test method is such a pass/fail comparison and an analysis of any one of the liquid fractions of the extract indicates that the concentration of the target analyte is so high that, even after accounting for dilution from the other fractions of the extract, it would be equal to or above an acceptance concentration level, then the waste fails the test. In such a case it may not be necessary to analyze the remaining fractions of the extract.  
1.5 This test method is intended to provide an extract suitable for the measurement of the concentration of analytes that will not volatilize under the conditions of the test method.  
1.6 Presence of volatile analytes may be established if an analysis of the extract obtained using this test method detects the target volatile analyte. If its concentration is equal to or exceeds an acceptance level for that analyte, the waste fails the test. However, extract from this test method shall not be used to determine the concentration of volatile organic analytes.  
1.7 This test method is intended to describe only the procedure for performing a batch extraction. It does not describe all of the sampling and analytical requirements that may be associate...

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ASTM
ASTM D5284-09(2023)(Test Method)
Standard Test Method for Sequential Batch Extraction of Waste with Acidic Extraction Fluid

SIGNIFICANCE AND USE
4.1 This test method is intended as a means for obtaining sequential extracts of a waste. The extracts may be used to estimate the release of certain constituents of the waste under the laboratory conditions described in this test method.  
4.2 The pH of the extraction fluid used in this test method is to reflect the pH of acidic precipitation in the geographic region in which the waste being tested is to be disposed.
Note 1: Possible sources of information concerning the pH of precipitation in the geographic region of interest include state and federal environmental agencies, state universities, libraries, etc.  
Note 2: For sequential batch extraction of waste using a nonacidic extraction fluid, see Test Method D4793.  
4.3 An intent of this test method is for the final pH of each of the extracts to reflect the interaction of the extractant with the buffering capacity of the waste.  
4.4 This test method is not intended to provide extracts that are representative of the actual leachate produced from a waste in the field or to produce extracts to be used as the sole basis of engineering design.  
4.5 This test method has not been demonstrated to simulate actual disposal site leaching conditions.  
4.6 This test method produces extracts that are amenable to the determination of both major and minor (trace) constituents. When minor constituents are being determined, it is especially important that precautions be taken in sample storage and handling to avoid possible contamination of the samples.  
4.7 This test method has been tested to determine its applicability to certain inorganic components in the waste. This test method has not been tested for applicability to organic substances, volatile matter (see Note 5), or biologically active samples.  
4.8 The agitation technique, rate, liquid-to-solid ratio, and filtration conditions specified in the procedure may not be suitable for extracting all types of wastes (see Sections 7 and 8 and Appendix X1).
SCOPE
1.1 This test method provides a procedure for the sequential leaching of a waste containing at least 5 % dry solids in order to generate solutions to be used to determine the constituents leached under the specified testing conditions.  
1.2 This test method calls for the shaking of a known weight of waste with acidic extraction fluid of a specified composition as well as the separation of the liquid phase for analysis. The pH of the extraction fluid is to reflect the pH of acidic precipitation in the geographic region in which the waste being tested is to be disposed. The procedure is conducted ten times in sequence on the same sample of waste, and it generates ten solutions.  
1.3 This test method is intended to describe the procedure for performing sequential batch extractions only. It does not describe all types of sampling and analytical requirements that may be associated with its application.  
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM D4793-09(2023)(Test Method)
Standard Test Method for Sequential Batch Extraction of Waste with Water

SIGNIFICANCE AND USE
4.1 This test method is intended as a means for obtaining sequential extracts of a waste. The extracts may be used to estimate the release of certain constituents of the waste under the laboratory conditions described in this test method.  
4.2 This test method is not intended to provide extracts that are representative of the actual leachate produced from a waste in the field or to produce extracts to be used as the sole basis of engineering design.  
4.3 This test method is not intended to simulate site-specific leaching conditions. It has not been demonstrated to simulate actual disposal site leaching conditions.  
4.4 An intent of this test method is that the final pH of each of the extracts reflects the interaction of the extractant with the buffering capacity of the waste.  
4.5 An intent of this test method is that the water extractions reflect conditions where the waste is the dominant factor in determining the pH of the extracts.  
4.6 This test method produces extracts that are amenable to the determination of both major and minor constituents. When minor constituents are being determined, it is especially important that precautions are taken in sample storage and handling to avoid possible contamination of the samples.  
4.7 This test method has been tested to determine its applicability to certain inorganic components in the waste. This test method has not been tested for applicability to organic substances, volatile matter (see Note 3 in 5.15), or biologically active samples.  
4.8 The agitation technique, rate, liquid-to-solid ratio, and filtration conditions specified in the procedure may not be suitable for extracting all types of wastes (see Sections 7, 8, and the discussion in Appendix X1).
SCOPE
1.1 This test method is a procedure for the sequential leaching of a waste containing at least five percent solids to generate solutions to be used to determine the constituents leached under the specified testing conditions.  
1.2 This test method calls for the shaking of a known weight of waste with water of a specified purity and the separation of the aqueous phase for analysis. The procedure is conducted ten times in sequence on the same sample of waste and generates ten aqueous solutions.  
1.3 This test method is intended to describe the procedure for performing sequential batch extractions only. It does not describe all types of sampling and analytical requirements that may be associated with its application.  
1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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