ASTM D 2837 : 2022
Superseded
A superseded Standard is one, which is fully replaced by another Standard, which is a new edition of the same Standard.
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Standard Test Method for Obtaining Hydrostatic Design Basis for Thermoplastic Pipe Materials or Pressure Design Basis for Thermoplastic Pipe Products
Hardcopy , PDF
25-07-2024
English
15-03-2022
Committee |
F 17
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DocumentType |
Test Method
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Pages |
17
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PublisherName |
American Society for Testing and Materials
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Status |
Superseded
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SupersededBy | |
Supersedes |
1.1This test method describes two essentially equivalent procedures: one for obtaining a long-term hydrostatic strength category based on stress, referred to herein as the hydrostatic design basis (HDB); and the other for obtaining a long-term hydrostatic strength category based on pressure, referred to herein as the pressure design basis (PDB). The HDB is based on the material's long-term hydrostatic strength (LTHS),and the PDB is based on the product's long-term hydrostatic pressure-strength (LTHSP). The HDB is a material property and is obtained by evaluating stress rupture data derived from testing pipe made from the subject material. The PDB is a product specific property that reflects not only the properties of the material(s) from which the product is made, but also the influence on product strength by product design, geometry, and dimensions and by the specific method of manufacture. The PDB is obtained by evaluating pressure rupture data. The LTHS is determined by analyzing stress versus time-to-rupture (that is, stress-rupture) test data that cover a testing period of not less than 10 000 h and that are derived from sustained pressure testing of pipe made from the subject material. The data are analyzed by linear regression to yield a best-fit log-stress versus log time-to-fail straight-line equation. Using this equation, the material's mean strength at the 100 000-h intercept (LTHS) is determined by extrapolation. The resultant value of the LTHS determines the HDB strength category to which the material is assigned. The LTHSP is similarly determined except that the determination is based on pressure versus time data that are derived from a particular product. The categorized value of the LTHSP is the PDB. An HDB/PDB is one of a series of preferred long-term strength values. This test method is applicable to all known types of thermoplastic pipe materials and thermoplastic piping products. It is also applicable for any practical temperature and medium that yields stress-rupture data that exhibit an essentially straight-line relationship when plotted on log stress (pound-force per square inch) or log pressure (pound-force per square in. gage) versus log time-to-fail (hours) coordinates, and for which this straight-line relationship is expected to continue uninterrupted through at least 100 000 h.
1.2Unless the experimentally obtained data approximate a straight line, when calculated using log-log coordinates, it is not possible to assign an HDB/PDB to the material. Data that exhibit high scatter or a “knee” (a downward shift, resulting in a subsequently steeper stress-rupture slope than indicated by the earlier data) but which meet the requirements of this test method tend to give a lower forecast of LTHS/LTHSP. In the case of data that exhibit excessive scatter or a pronounced “knee,” the lower confidence limit requirements of this test method are not met and the data are classified as unsuitable for analysis.
1.3A fundamental premise of this test method is that when the experimental data define a straight-line relationship in accordance with this test method's requirements, this straight line may be assumed to continue beyond the experimental period, through at least 100 000 h (the time intercept at which the material's LTHS/LTHSP is determined). In the case of polyethylene piping materials, this test method includes a supplemental requirement for the “validating” of this assumption. No such validation requirements are included for other materials (see Note 1). Therefore, in all these other cases, it is up to the user of this test method to determine based on outside information whether this test method is satisfactory for the forecasting of a material's LTHS/LTHSP for each particular combination of internal/external environments and temperature.
Note 1:Extensive long-term data that have been obtained on commercial pressure pipe grades of polyvinyl chloride (PVC), polybutylene (PB), and cross linked polyethylene (PEX) materials have shown that this assumption is appropriate for the establishing of HDB's for these materials for water and for ambient temperatures. Refer to Note 2 and Appendix X1 for additional information.
1.4The experimental procedure to obtain individual data points shall be as described in Test Method D1598, which forms a part of this test method. When any part of this test method is not in agreement with Test Method D1598, the provisions of this test method shall prevail.
1.5General references are included at the end of this test method.
1.6This 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.
1.7The values stated in inch-pound units are to be regarded as the standard. The values given in parentheses are for information only and are not considered the standard.
Note 2:Over 3000 sets of data, obtained with thermoplastic pipe and piping assemblies tested with water, natural gas, and compressed air, have been analyzed by the Plastic Pipe Institute's (PPI) Hydrostatic Stress Board2. None of the currently commercially offered compounds included in PPI TR-4, “PPI Listing of Hydrostatic Design Basis (HDB), Hydrostatic Design Stress (HDS), Strength Design Basis (SDB), Pressure Design Basis (PDB) and Minimum Required Strength (MRS) Ratings for Thermoplastic Piping Materials or Pipe” exhibit knee-type plots at the listed temperature, that is, deviate from a straight line in such a manner that a marked drop occurs in stress at some time when plotted on equiscalar log-log coordinates. Ambient temperature stress-rupture data that have been obtained on a number of the listed materials and that extend for test periods over 120 000 h give no indication of “knees.” However, stress-rupture data which have been obtained on some thermoplastic compounds that are not suitable or recommended for piping compounds have been found to exhibit a downward trend at 23 °C (73 °F) in which the departure from linearity appears prior to this test method's minimum testing period of 10 000 h. In these cases, very low results are obtained or the data are found unsuitable for extrapolation when they are analyzed by this test method.
Extensive evaluation of stress-rupture data by PPI and others has also indicated that in the case of some materials and under certain test conditions, generally at higher test temperatures, a departure from linearity, or “down-turn”, may occur beyond this test method's minimum required data collection period of 10 000 h. A PPI study has shown that in the case of polyethylene piping materials that are projected to exhibit a “down-turn” prior to 100 000 h at 73 °F, the long-term field performance of these materials is prone to more problems than in the case of materials which have a projected “down-turn” that lies beyond the 100 000-h intercept. In response to these observations, a supplemental “validation” requirement for PE materials has been added to this test method in 1988. This requirement is designed to reject the use of this test method for the estimating of the long-term strength of any PE material for which supplemental elevated temperature testing fails to validate this test method's inherent assumption of continuing straight-line stress-rupture behavior through at least 100 000 h at 23 °C (73 °F).
When applying this test method to other materials, appropriate consideration should be given to the possibility that for the particular grade of material under evaluation and for the specific conditions of testing, particularly, when higher test temperatures and aggressive environments are involved, there may occur a substantial “down-turn” at some point beyond the data collection period. The ignoring of this possibility may lead to an overstatement by this test method of a material's actual LTHS/LTHSP. To obtain sufficient assurance that this test method's inherent assumption of continuing linearity through at least 100 000 h is appropriate, the user should consult and consider information outside this test method, including very long-term testing or extensive field experience with similar materials. In cases for which there is insufficient assurance of the continuance of the straight-line behavior that is defined by the experimental data, the use of other test methods for the forecasting of long-term strength should be considered (see Appendix X1).
1.8This 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 F 2619/F2619M : 2020 | Standard Specification for High-Density Polyethylene (PE) Line Pipe |
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ASTM F 2968/F2968M : 2021 | Standard Specification for Crosslinked Polyethylene (PEX) Pipe for Gas Distribution Applications |
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ASTM D 3350 : 2021 | Standard Specification for Polyethylene Plastics Pipe and Fittings Materials |
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ASTM F 1282 : 2017 | Standard Specification for Polyethylene/Aluminum/Polyethylene (PE-AL-PE) Composite Pressure Pipe |
ASTM F 1483 : 2017 | Standard Specification for Oriented Poly(Vinyl Chloride), PVCO, Pressure Pipe |
ASTM F 2160 : 2016 | Standard Specification for Solid Wall High Density Polyethylene (HDPE) Conduit Based on Controlled Outside Diameter (OD) |
ASTM F 3181 : 2016 | Standard Test Method for The Un-notched, Constant Ligament Stress Crack Test (UCLS) for HDPE Materials Containing Post- Consumer Recycled HDPE |
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ASTM F 3181 : 2016 : R2023 | Standard Test Method for The Un-notched, Constant Ligament Stress Crack Test (UCLS) for HDPE Materials Containing Post- Consumer Recycled HDPE |
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ASTM F 2735 : 2023 | Standard Specification for Plastic Insert Fittings For SDR9 Cross-linked Polyethylene (PEX) and Polyethylene of Raised Temperature (PE-RT) Tubing |
ASTM F 1282 : 2023 : REV A | Standard Specification for Polyethylene/Aluminum/Polyethylene (PE-AL-PE) Composite Pressure Pipe |
ASTM D 2239 : 2022 | Standard Specification for Polyethylene (PE) Plastic Pipe (SIDR-PR) Based on Controlled Inside Diameter |
ASTM F 2769 : 2024 | Standard Specification for Polyethylene of Raised Temperature (PE-RT) Plastic Hot and Cold-Water Tubing and Distribution Systems |
ASTM F 3346 : 2024 | Standard Specification for Polyethylene of Raised Temperature/Aluminum/Polyethylene of Raised Temperature (PE-RT/AL/PE-RT) Composite Pressure Pipe |
ASTM F 3524/F3524M : 2023 | Standard Specification for Polyamide-12 (PA12) Line Pipe |
ASTM F 1483 : 2023 | Standard Specification for Oriented Poly(Vinyl Chloride), PVCO, Pressure Pipe |
ASTM D 3035 : 2022 | Standard Specification for Polyethylene (PE) Plastic Pipe (DR-PR) Based on Controlled Outside Diameter |
ASTM F 2817 : 2013 : R2023 | Standard Specification for Poly (Vinyl Chloride) (PVC) Gas Pressure Pipe and Fittings For Maintenance or Repair |
ASTM F 442/F442M : 2023 | Standard Specification for Chlorinated Poly(Vinyl Chloride) (CPVC) Plastic Pipe (SDR–PR) |
ASTM F 3378/F3378M : 2022 | Standard Specification for Crosslinkable Polyethylene (CX-PE) Pipe |
ASTM F 2207 : 2006 : R2023 | Standard Specification for Cured-in-Place Pipe Lining System for Rehabilitation of Metallic Gas Pipe |
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ASTM F 2159 : 2023 : REV A | Standard Specification for Plastic Insert Fittings Utilizing a Copper Crimp Ring, or Alternate Stainless Steel Clamps for SDR9 Crosslinked Polyethylene (PEX) Tubing and SDR9 Polyethylene of Raised Temperature (PE-RT) Tubing |
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ASTM F 3253 : 2024 | Standard Specification for Crosslinked Polyethylene (PEX) Tubing with Oxygen Barrier for Hot- and Cold-Water Hydronic Distribution Systems |
ASTM F 2896 : 2023 | Standard Specification for Reinforced Polyethylene Composite Pipe For The Transport Of Oil And Gas And Hazardous Liquids |
ASTM D 2846/D2846M : 2024 | Standard Specification for Chlorinated Poly(Vinyl Chloride) (CPVC) Plastic Hot- and Cold-Water Distribution Systems |
ASTM F 412 : 2023 | Standard Terminology Relating to Plastic Piping Systems |
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ASTM F 894 : 2024 | Standard Specification for Polyethylene (PE) Large Diameter Profile Wall Sewer and Drain Pipe |
ASTM F 714 : 2024 | Standard Specification for Polyethylene (PE) Plastic Pipe (DR-PR) Based on Outside Diameter |
ASTM D 2241 : 2024 | Standard Specification for Poly(Vinyl Chloride) (PVC) Pressure-Rated Pipe (SDR Series) |
ASTM F 441/F441M : 2023 | Standard Specification for Chlorinated Poly(Vinyl Chloride) (CPVC) Plastic Pipe, Schedules 40 and 80 |
ASTM F 2261 : 2006 : R2023 | Standard Test Method for Pressure Rating Poly(Vinyl Chloride) (PVC) Plastic Pipe Fittings, Schedule 40 and 80 Socket-Type |
ASTM F 877 : 2024 | Standard Specification for Crosslinked Polyethylene (PEX) Hot- and Cold-Water Distribution Systems |
ASTM F 2945 : 2018 : R2023 | Standard Specification for Polyamide 11 Gas Pressure Pipe, Tubing, and Fittings |
ASTM D 1243 : 2015 | Standard Test Method for Dilute Solution Viscosity of Vinyl Chloride Polymers |
ASTM E 29 : 2013 : R2019 | Standard Practice for Using Significant Digits in Test Data to Determine Conformance with Specifications |
ASTM D 1598 : 2023 | Standard Test Method for Time-to-Failure of Plastic Pipe Under Constant Internal Pressure |
ASTM D 1243 : 2022 | Standard Test Method for Dilute Solution Viscosity of Vinyl Chloride Polymers |
ASTM D 1243 : 2022 : EDT 1 | Standard Test Method for Dilute Solution Viscosity of Vinyl Chloride Polymers |
ASTM E 29 : 2022 | Standard Practice for Using Significant Digits in Test Data to Determine Conformance with Specifications |
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