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ASTM E898-88(2005)

(Test Method)

Standard Test Method of Testing Top-Loading, Direct-Reading Laboratory Scales and Balances

Standard Test Method of Testing Top-Loading, Direct-Reading Laboratory Scales and Balances

SIGNIFICANCE AND USE
This method will enable the user to develop information concerning the precision and accuracy of weighing instruments. In addition, results obtained using this method will permit the most advantageous use of the instrument. Weaknesses as well as strengths of the instrument should become apparent. It is not the intent of this method to compare similar instruments of different manufacture, but to enable the user to choose a suitable instrument.
SCOPE
1.1 This test method covers the determination of characteristics of top-loading, direct-reading laboratory scales and balances. Laboratory scales of the top-loading type may have capacities from a few grams up to several kilograms. Resolution may be from 1/1000 of capacity to 1/1 000 000 or more. This method can be used for any of these instruments and will serve to measure the most important characteristics that are of interest to the user. The characteristics to be measured include the following:
1.1.1 warm-up,
1.1.2 off center errors,
1.1.3 repeatability, reproducibility, and precision,
1.1.4 accuracy and linearity,
1.1.5 hysteresis,
1.1.6 settling time,
1.1.7 temperature effects,
1.1.8 vernier or micrometer calibration, and
1.1.9 resistance to external disturbances.
1.2 The types of scales that can be tested by this method are of stabilized pan design wherein the sample pan does not tilt out of a horizontal plane when the sample is placed anywhere on the pan surface. The pan is located generally above the measuring mechanism with no vertical obstruction, except for draft shields. Readings of weight may be obtained from an optical scale, from a digital display, or from a mechanical dial. Weighing mechanisms may be of the deflecting type, using gravity or a spring as the transducer, or may be a force-balance system wherein an electromagnetic, pneumatic, hydraulic, or other force is used to counterbalance the weight of the sample. Other force-measuring devices may be tested by this method as long as a sample placed on a receiving platform produces an indication that is substantially a linear function of the weight of the sample.
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 limitations prior to use.

General Information

Status
Historical
Publication Date
30-Sep-2005
ICS
17.100 - Measurement of force, weight and pressure
Technical Committee
E41 - Laboratory Apparatus
Drafting Committee
E41.06 - Laboratory Instruments and Equipment
Current Stage
Ref Project

Relations

Replaces
ASTM E898-88(2000) - Standard Method of Testing Top-Loading, Direct-Reading Laboratory Scales and Balances
Effective Date
01-Oct-2005
Replaced By
ASTM E898-88(2013) - Standard Test Method of Testing Top-Loading, Direct-Reading Laboratory Scales and Balances
Effective Date
01-Dec-2013
Referred By
ASTM D6489-99(2020) - Standard Test Method for Determining the Water Absorption of Hardened Concrete Treated With a Water Repellent Coating
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01-Oct-2005
Referred By
ASTM E542-22 - Standard Practice for Gravimetric Calibration of Laboratory Volumetric Instruments
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01-Oct-2005
Referred By
ASTM D8293-22 - Standard Guide for Evaluating and Expressing the Uncertainty of Radiochemical Measurements
Effective Date
01-Oct-2005
Referred By
ASTM D7578-20 - Standard Guide for Calibration Requirements for Elemental Analysis of Petroleum Products and Lubricants
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ASTM D5907-18 - Standard Test Methods for Filterable Matter (Total Dissolved Solids) and Nonfilterable Matter (Total Suspended Solids) in Water
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ASTM D7542-21 - Standard Test Method for Air Oxidation of Carbon and Graphite in the Kinetic Regime
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ASTM E898-88(2005) - Standard Test Method of Testing Top-Loading, Direct-Reading Laboratory Scales and BalancesASTM E898-88(2005) - Standard Test Method of Testing Top-Loading, Direct-Reading Laboratory Scales and Balances
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ASTM E898-88(2005) - Standard Test Method of Testing Top-Loading, Direct-Reading Laboratory Scales and Balances
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Standards Content (Sample)


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: E898 − 88 (Reapproved2005)
Standard Test Method of Testing
Top-Loading, Direct-Reading Laboratory Scales and
Balances
This standard is issued under the fixed designation E898; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision.Anumber in parentheses indicates the year of last reapproval.A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
INTRODUCTION
Thismethodisdesignedtotestcommonlyusedlaboratoryscalesthatreadtheentirerangeofweight
up to the capacity without manual operation. In essence, the entire reading range is on-scale and no
manipulation of weights, riders, or dials is required; except some scales with optical reading devices
may require the operation of a micrometer dial to interpolate the final one or two significant figures.
1. Scope other force is used to counterbalance the weight of the sample.
Otherforce-measuringdevicesmaybetestedbythismethodas
1.1 This test method covers the determination of character-
long as a sample placed on a receiving platform produces an
istics of top-loading, direct-reading laboratory scales and
indicationthatissubstantiallyalinearfunctionoftheweightof
balances. Laboratory scales of the top-loading type may have
the sample.
capacities from a few grams up to several kilograms. Resolu-
1.3 This standard does not purport to address all of the
tion may be from 1/1000 of capacity to 1/1000000 or more.
safety concerns, if any, associated with its use. It is the
This method can be used for any of these instruments and will
responsibility of the user of this standard to establish appro-
serve to measure the most important characteristics that are of
priate safety and health practices and determine the applica-
interest to the user. The characteristics to be measured include
bility of regulatory limitations prior to use.
the following:
1.1.1 warm-up,
2. Summary of Method
1.1.2 off center errors,
1.1.3 repeatability, reproducibility, and precision,
2.1 Throughout this method, the instrument is used in the
1.1.4 accuracy and linearity,
manner for which it is intended. One or more weights are used
1.1.5 hysteresis,
to test each of the characteristics, and the results are expressed
1.1.6 settling time,
intermsoftheleastcountorultimatereadabilityofthedisplay.
1.1.7 temperature effects,
1.1.8 vernier or micrometer calibration, and
3. Terminology
1.1.9 resistance to external disturbances.
3.1 Definitions of Terms Specific to This Standard:
1.2 Thetypesofscalesthatcanbetestedbythismethodare
3.1.1 accuracy—the degree of agreement of the measure-
of stabilized pan design wherein the sample pan does not tilt
ment with the true value of the quantity measured.
out of a horizontal plane when the sample is placed anywhere
3.1.2 capacity—the maximum weight load specified by the
on the pan surface. The pan is located generally above the
manufacturer. In most instruments, the maximum possible
measuring mechanism with no vertical obstruction, except for
reading will exceed the capacity by a small amount.
draft shields. Readings of weight may be obtained from an
3.1.3 full-scale calibration—the indicated reading when a
optical scale, from a digital display, or from a mechanical dial.
standardweightequaltothefullscaleindicationofthescaleis
Weighing mechanisms may be of the deflecting type, using
placed on the sample pan after the device has been correctly
gravityoraspringasthetransducer,ormaybeaforce-balance
zeroed. Usually some means is provided by the manufacturer
system wherein an electromagnetic, pneumatic, hydraulic, or
to adjust the full scale indication to match the weight of the
standard.
This test method is under the jurisdiction of ASTM Committee E41 on
Laboratory Apparatus and is the direct responsibility of Subcommittee E41.06 on
Weighing Devices.
Current edition approved Oct. 1, 2005. Published December 2005. Originally ANSI/ISA S51.1 “Process Instrumentation Technology”. Available from
approved in 1982. Last previous edition approved in 2000 as E898–88(2000). AmericanNationalStandardsInstitute(ANSI),25W.43rdSt.,4thFloor,NewYork,
DOI: 10.1520/E0898-88R05. NY 10036.
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
E898 − 88 (2005)
3.1.4 linearity—the degree to which a graph of weight 5. Apparatus
values indicated by a scale vs. the true values of the respective
5.1 Manufacturer’s Manual.
test weights approximates a straight line. For a quantitative
5.2 Standard Weights—A set of weights up to the capacity
statement of linearity errors, the concept of terminal-based
of the scale with sufficient subdivisions of weight so that
non-linearityisrecommended,suchas,themaximumdeviation
incrementsofabout10%ofthecapacityuptothecapacitycan
of the calibration curve (average of the readings at increasing
be tested.
and decreasing test load, respectively) from a straight line
drawnthroughtheupperandlowerendpointsofthecalibration 5.3 Thermometer, room temperature, with a resolution of at
curve.
least 1°C.
3.1.5 off-center errors—differences in indicated weight
5.4 Stop-Watch, reading to ⁄5 s.
when a sample weight is shifted to various positions on the
6. Preparation
weighing area of the sample pan.
6.1 Make sure that the scale and weights are clean.
3.1.6 hysteresis—difference in weight values indicated at a
given test load depending on whether the test load was arrived
6.2 Place the standard weights near the instrument.
at by an increase or a decrease from the previous load on the
6.3 Place the thermometer on the bench in such a position
scale.
that it can be read without being touched.
3.1.7 repeatability—closeness of agreement of the indicated
6.4 Allow the instrument and the weights to sit undisturbed
values for successive weighings of the same load, under
for at least 2 h with the balance turned off. Monitor the
essentially the same conditions, approaching from the same
temperatureduringthistimetomakesurethatthereisnomore
direction (such as, disregarding hysteresis).
than approximately 2°C variation over the last hour before
3.1.8 reproducibility—closeness of agreement of the indi-
beginning the test.
cated values when weighings of the same load are made over
6.5 Read the manufacturer’s instructions carefully. During
a period of time under essentially the same conditions but not
each step of the test procedure, the instrument should be used
limited to the same direction of approach (such as, hysteresis
in the manner recommended by the manufacturer. Know the
errors are included).
location of any switches, dials, or buttons as well as their
3.1.9 precision—the smallest amount of weight difference
functions.
between closely similar loads that a balance is capable of
7. Test Procedure
detecting. The limiting factor is either the size of the digital
stepoftheindicatorreadoutortherepeatabilityoftheindicated
7.1 Warm-up Test:
values.
7.1.1 If it is required in the normal operation of the scale to
turn it “on” as an operation separate from weighing, perform
3.1.10 standard deviation—used as a quantitative figure of
that operation simultaneously with the starting of the stop-
merit when making statements on the repeatability, reproduc-
watch.
ibility or precision of a balance.
7.1.2 If a zeroing operation is required, do it promptly.
3.1.11 readability—the value of the smallest unit of weight
Record the temperature.
that can be read without estimation. In the case of digital
7.1.3 At the end of 1 min, read and record the indication
instruments, the readability is the smallest increment of the
with the pan empty.
least significant digit (for example, 1, 2 or 5). Optical scales
7.1.4 At the center of the sample pan place a standard
may have a vernier or micrometer for subdividing the smallest
weight nearly equal to but not exceeding 98% of the capacity
scale division. In that case, the smallest graduation of the
of the scale. If the scale allows no weight readings above the
vernier or micrometer represents the readability.
stated nominal capacity, then this test should be performed
3.1.12 standard weight—any weight whose mass is given.
with standard weights equal to 90% of capacity. When the
Since weights are not always available with documented
indication is steady, record the indication and remove the
corrections, weights defined by class may be used if the class
weight from the pan.
chosen has sufficiently small limits and there is an understand-
7.1.5 At the end of 5 min, repeat steps 7.1.3 and 7.1.4
ing that errors perceived as being instrumental in nature could
without rezeroing.
be attributed to incorrectly adjusted weights.
7.1.6 At the end of 30 min, repeat again.
7.1.7 At the end of 1 h, repeat again. Record the tempera-
4. Significance and Use
ture.
7.1.8 Compute for each measurement as follows:
4.1 Thismethodwillenabletheusertodevelopinformation
concerning the precision and accuracy of weighing instru-
k 5 W/ I 2 I (1)
~ !
t w o
ments. In addition, results obtained using this method will
permit the most advantageous use of the instrument. Weak-
where:
nesses as well as strengths of the instrument should become
I = indication with the standard weight on the pan,
w
apparent. It is not the intent of this method to compare similar
I = indication with pan empty,
o
instruments of different manufacture, but to enable the user to
W = known or assumed value of the standard weight, and
choose a suitable instrument.
E898 − 88 (2005)
Operation Weight on Pan Balance Reading
k = calibration factor for time t.
t
1 nil 0
7.1.9 Plot the values of k against the time (1 min, 5 min, 30
t
2 ⁄2 capacity W1
min, and 60 min). The time at which k apparently no longer
t
3 full capacity W2
drifts in one direction can be assumed to be the warm-up time 1
4 ⁄2 capacity W18
5 nil Z
required.
7.1.10 If there is a
...

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5.2 The data developed by this test method may be used for the purpose of sizing deflagration vents in conjunction with the nomographs and equations published in NFPA 68, ISO 6184/1, or VDI 3673.  
5.3 The values obtained by this testing technique are specific to the sample tested and the method used and are not to be considered intrinsic material constants.  
5.4 For dusts with low KSt values, discrepancies have been observed between tests in 20-L and 1-m3 chambers. A strong ignitor may overdrive a 20-L chamber, as discussed in Test Method E1515 and Refs (1-4).8 Conversely, more recent testing has shown that some metal dusts can be prone to underdriving in the 20-L chamber, exhibiting significantly lower KSt values than in a 1-m3 chamber (5). Ref (6) provides supporting calculations showing that a test vessel of at least 1-m3 of volume is necessary to obtain the maximum explosibility index for a burning dust cloud having an abnormally high flame temperature. In these two overdriving and underdriving scenarios described above, it is therefore recommended to perform tests in 1-m3 or larger calibrated test vessels in order to measure dusts explosibility parameters accurately.
Note 5: Ref (2) concluded that dusts with KSt values below 45 bar m/s when measured in a 20-L chamber with a 10 000-J ignitor, may not be explosible when tested in a 1-m3 chamber with a 10 000-J ignitor. Ref (2) and unpublished testing has also shown that in some cases the KSt values measured in the 20-L chamber can be lower than those measured in the 1-m3 chamber. Refs (1) and (3) found that for some dusts, it was necessary to use lower ignition energy in the 20-L chamber in order to match MEC or MIC test data in a 1-m3 chamber. If a dust has measurable (nonzero) Pmax and KSt values with a 5000 or 10 000-J ignitor when tested in a 20-L chamber but no measurable Pmax and ...
SCOPE
1.1 Purpose. The purpose of this test method is to provide standard test methods for characterizing the “explosibility” of dust clouds in two ways, first by determining if a dust is “explosible,” meaning a cloud of dust dispersed in air is capable of propagating a deflagration, which could cause a flash fire or explosion; or, if explosible, determining the degree of “explosibility,” meaning the potential explosion hazard of a dust cloud as characterized by the dust explosibility parameters, maximum explosion pressure, Pmax; maximum rate of pressure rise, (dP/dt)max; and explosibility index, KSt.  
1.2 Limitations. Results obtained by the application of the methods of this standard pertain only to certain combustion characteristics of dispersed dust clouds. No inference should be drawn from such results relating to the combustion characteristics of dusts in other forms or conditions (for example, ignition temperature or spark ignition energy of dust clouds, ignition properties of dust layers on hot surfaces, ignition of bulk dust in heated environments, etc.)  
1.3 Use. It is intended that results obtained by application of this test be used as elements of a dust hazard analysis (DHA) that takes into account other pertinent risk factors; and in the specification of explosion prevention systems (see, for example NFPA 68, NFPA 69, and NFPA 652) when used in conjunction with approved or recognized design methods by those skilled in the art.
Note 1: Historically, the evaluation of the deflagration parameters of maximum pressure and maximum rate of pressure rise has been performed using a 1.2-L Hartmann Apparatus. Test Method E789, which describes this method, has been withdrawn. The use of data obtained from the test method in the design of explosion protection systems is not recommended.  
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....

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ASTM
ASTM F2569-11(2019)(Test Method)
Standard Test Method for Evaluating the Force Reduction Properties of Surfaces for Athletic Use

SIGNIFICANCE AND USE
5.1 The force reduction property is just one of the important properties of a surface used for athletic activity. It may be an indicator of the performance, safety, comfort, or suitability of the surface.  
5.2 Manufacturers of athletic surfaces may use this test method to evaluate the effects of design changes on the impact forces generated on the surface.  
5.3 Facility owners may use this standard to evaluate the performance of existing sport/athletic surfaces. Results may be useful during the selection process for a replacement surface, or for an additional athletic surface being added to the facility.  
5.4 Facility owners may also use this test method to verify that newly installed surfaces perform at or near the levels included in project specifications.
SCOPE
1.1 This test method covers the quantitative measurement and normalization of impact forces generated through a mechanical impact test on an athletic surface. The impact forces simulated in this test method are intended to represent those produced by lower extremities of an athlete during landing events on sport or athletic surfaces.  
1.2 This test method may be applied to any surface where athletic activity may be conducted.  
1.3 The test methods described are applicable in both laboratory and field settings.  
1.4 The values stated in SI units are to be regarded as standard. The values given in parentheses are for information only.  
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 E74-18e1(Practice)
Standard Practices for Calibration and Verification for Force-Measuring Instruments

SIGNIFICANCE AND USE
4.1 Testing machines that apply and indicate force are in general use in many industries. Practices E4 has been written to provide a practice for the force verification of these machines. A necessary element in Practices E4 is the use of force-measuring instruments whose force characteristics are known to be traceable to the SI. Practices E74 describes how these force-measuring instruments are to be calibrated. The procedures are useful to users of testing machines, manufacturers and providers of force-measuring instruments, calibration laboratories that provide the calibration of the instruments and the documents of traceability, service organizations that use the force-measuring instruments to verify testing machines, and testing laboratories performing general structural test measurements.
SCOPE
1.1 The purpose of these practices is to specify procedures for the calibration of force-measuring instruments. Procedures are included for the following types of instruments:  
1.1.1 Elastic force-measuring instruments, and  
1.1.2 Force-multiplying systems, such as balances and small platform scales.  
Note 1: Verification by deadweight loading is also an acceptable method of verifying the force indication of a testing machine. Tolerances for weights for this purpose are given in Practices E4; methods for calibration of the weights are given in NIST Technical Note 577(1)2, Methods of Calibrating Weights for Piston Gages.  
1.2 The values stated in SI units are to be regarded as the standard. Other metric and inch-pound values are regarded as equivalent when required.  
1.3 These practices are intended for the calibration of static force measuring instruments. It is not applicable for dynamic or high speed force calibrations, nor can the results of calibrations performed in accordance with these practices be assumed valid for dynamic or high speed force measurements.  
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 E1194-17(Test Method)
Standard Test Method for Vapor Pressure

SIGNIFICANCE AND USE
5.1 Vapor pressure values can be used to predict volatilization rates (5). Vapor pressures, along with vapor-liquid partition coefficients (Henry's Law constant) are used to predict volatilization rates from liquids such as water. These values are thus particularly important for the prediction of the transport of a chemical in the environment (6).
SCOPE
1.1 This test method describes procedures for measuring the vapor pressure of pure liquid or solid compounds. No single technique is able to measure vapor pressures from 1 × 10−11 to 100 kPa (approximately 10−10 to 760 torr). The subject of this standard is gas saturation which is capable of measuring vapor pressures from 1 × 10–11 to 1 kPa (approximately 10–10 to 10 torr). Other methods, such as isoteniscope and differential scanning calorimetry (DSC) are suitable for measuring vapor pressures above 0.1 kPa An isoteniscope (standard) procedure for measuring vapor pressures of liquids from 1 × 10−1 to 100 kPa (approximately 1 to 760 torr) is available in Test Method D2879. A DSC (standard) procedure for measuring vapor pressures from 2 × 10−1 to 100 kPa (approximately 1 to 760 torr) is available in Test Method E1782. A gas-saturation procedure for measuring vapor pressures from 1 × 10−11 to 1 kPa (approximately 10−10 to 10 torr) is presented in this test method. All procedures are subjects of U.S. Environmental Protection Agency Test Guidelines.  
1.2 The gas saturation method is very useful for providing vapor pressure data at normal environmental temperatures (–40 to +60°C). At least three temperature values should be studied to allow definition of a vapor pressure-temperature correlation. Values determined should be based on temperature selections such that a measurement is made at 25°C (as recommended by IUPAC) (1),2 a value can be interpolated for 25°C, or a value can be reliably extrapolated for 25°C. Extrapolation to 25°C should be avoided if the temperature range tested includes a value at which a phase change occurs. Extrapolation to 25°C over a range larger than 10°C should also be avoided. If possible, the temperatures investigated should be above and below 25°C to avoid extrapolation altogether. The gas saturation method was selected because of its extended range, simplicity, and general applicability (2). Examples of results produced by the gas-saturation procedure during an interlaboratory evaluation are given in Table 1. These data have been taken from Reference (3).  (A) Sr is the estimated standard deviation within laboratories, that is, an average of the repeatability found in the separate laboratories.(B) SR is the square root of the component of variance between laboratories.(C) SR is the between-laboratory estimate of precision.  
1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard.  
1.4 This standard does not purport to address all of the safety problems, 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 limitations prior to use.

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