ASTM C963-00(2012)..
ASTM D4775/D4775M-09..
ASTM D642-00(2010)..
ASTM D7386-12
ASTM E920-97(2013)..
ASTM E921-97(2010)..
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ASTM F2338-09(2013)
Standard Test Method for Nondestructive Detection of Leaks in Packages by Vacuum Decay Method
Automaticky preložený názov:
Štandardná skúšobná metóda pre nedeštruktívne detekciu netesností balíčkov pomocou vákua Decay metódou
NORMA vydaná dňa 1.8.2013
Informácie o norme:
Označenie normy: ASTM F2338-09(2013)
Poznámka: NEPLATNÁ
Dátum vydania normy: 1.8.2013
Kód tovaru: NS-53600
Počet strán: 13
Približná hmotnosť: 39 g (0.09 libier)
Krajina: Americká technická norma
Kategória: Technické normy ASTM
Kategórie - podobné normy:
Anotácia textu normy ASTM F2338-09(2013) :
Keywords:
absolute pressure transducer, barrier performance, block, criteria parameters, differential pressure transducer, flexible packaging, food packages, gauge pressure transducer, hole leaks, holes, leaks, liquid leaks, mask, medical packages, non-destructive testing, package integrity monitoring, package integrity test, permeable packaging, pharmaceutical packages, porous barrier, porous barrier material, porous packaging, pressure change leak testing, pressure transducer, seal integrity monitoring
Doplňujúce informácie
| Significance and Use | |||
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5.1 Leaks in medical device, pharmaceutical, and food packages may result in the ingress of unwanted gases (most commonly oxygen), harmful microbiological, or particulate contaminants. Package leaks may appear as imperfections in the package components themselves or at the seal juncture between mated components. The ability to detect leaks is necessary to ensure consistency and integrity of packages. 5.2 After initial set-up and calibration, individual test operation may be semi-automatic, automatic, or manual. The test method permits non-destructive detection of leaks not visibly detectable. The test method does not require the introduction of any extraneous materials or substances, such as dyes or gases. However, it is important to physically mask or block off any package porous barrier surface during the test to prevent rapid loss of chamber vacuum resulting primarily from gas migration through the porous surface. Leak detection is based solely on the ability to detect the change in pressure inside the test chamber resulting from gas or vapor egress from a package challenged with vacuum. 5.3 This test is a useful research tool for optimizing package sealing parameters and for comparatively evaluating various packages and materials. This test method is also applicable to production settings as it is rapid, non-invasive, and non-destructive, making it useful for either 100 % on-line testing or to perform tests on a statistical sampling from the production operation. 5.4 Leak test results that exceed the permissible limits for the vacuum decay test are indicated by audible or visual signal responses, or both. |
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| 1. Scope | |||
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1.1 Test Packages—Packages that can be nondestructively evaluated by this test method include: 1.1.1 Rigid and semi-rigid non-lidded trays. 1.1.2 Trays or cups sealed with porous barrier lidding material. 1.1.3 Rigid, nonporous packages. 1.1.4 Flexible, nonporous packages. 1.2 Leaks Detected—This test method detects package leaks by measuring the rise in pressure (vacuum loss) in an enclosed evacuated test chamber containing the test package. Vacuum loss results from leakage of test package headspace gases and/or volatilization of test package liquid contents located in or near the leak. When testing for leaks that may be partially or completely plugged with the package’s liquid contents, the test chamber is evacuated to a pressure below the liquid’s vaporization pressure. All methods require a test chamber to contain the test package and a leak detection system designed with one or more pressure transducers. Test method sensitivities cited below were determined using specific product-package systems selected for the precision and bias studies summarized in Package ExamplesA |
Package Content Examples |
ASTM P&B Data Tables |
Target VacuumB |
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GAS LEAK TEST |
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Porous barrier lidded traysC |
Empty |
3, 4, 5 |
–400 mbar |
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Nonlidded traysC or cups |
Empty |
2 |
–400 mbar |
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Plastic screw capped bottlesC |
Solids (tablets, capsules, powders) |
6 |
–500 mbar |
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Glass syringesC |
Solids (lyophilized powders) |
7, 8 |
+250 mbar |
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ADDITIONAL GAS LEAK TEST PACKAGE APPLICATIONSA |
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Lidded (nonporous) trays or cups containing solid materials (for example, powders, tablets, capsules, devices) |
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Glass or plastic vials closed with elastomeric closures containing solid materials (for example, powders) |
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Glass or plastic vials closed with elastomeric closures, containing liquid materials, but with significant gas headspace volume |
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Flexible packages (for example pouches or bags) containing solid materials (for example, powders, devices) |
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LIQUID LEAK TEST (with or without gas
headspace) |
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Glass syringesC |
Liquids |
9, 10 |
+1 mbar |
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ADDITIONAL LIQUID LEAK TEST PACKAGE APPLICATIONSA |
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Ophthalmic dropper tip bottles containing liquid materials |
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Glass or plastic ampoules containing liquid materials |
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Glass or plastic vials with elastomeric closures containing liquid materials |
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Lidded (nonporous trays or cups) containing liquid materials |
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Flexible packages such as pouches or bags containing liquid materials |
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1.2.1 Trays or Cups (Non-lidded)
(Air Leakage)—Hole or crack defects in the wall of the tray/cup
of at least 50 μm in diameter can be detected. Nonlidded trays were
tested at a Target Vacuum of –4·E4 Pa (–400 mbar).
1.2.2 Trays Sealed with Porous Barrier Lidding Material (Headspace Gas Leakage)—Hole or crack defects in the wall of the tray/cup of at least 100 μm in diameter can be detected. Channel defects in the seal area (made using wires of 125 μm in diameter) can be detected. Severe seal bonding defects in both continuous adhesive and dot matrix adhesive package systems can be detected. Slightly incomplete dot matrix adhesive bonding defects can also be detected. All porous barrier lidding material packages were tested at a Target Vacuum of –4·E4 Pa (–400 mbar). The sensitivity of the test for porous lidded packages is approximately E-2 Pa·m3·s-1 using a calibrated volumetric airflow meter.
1.2.3 Rigid, Nonporous Packages (Headspace Gas Leakage)—Hole defects of at least 5 μm in diameter can be detected. Plastic bottles with screw caps were tested at a target vacuum of –5·E4 Pa (–500 mbar). Using a calibrated volumetric airflow meter, the sensitivity of the test is approximately E-3.4 Pa·m3·s-1 . Air-filled glass syringes were tested at a target vacuum of –7.5·E4 Pa (+250 mbar absolute) and again at a target vacuum of about +1 mbar absolute. The sensitivity of both tests is approximately E-4.1 Pa·m3·s -1 using a calibrated volumetric airflow meter.
1.2.4 Rigid, Nonporous Packages (Liquid Leakage)—Hole defects of at least 5 μm in diameter can be detected. This detection limit was verified using a population of water-filled glass syringes tested at a target vacuum of about +1 mbar absolute.
1.2.5 Flexible, Nonporous Packages (Gas or Liquid Leakage)—Such packages may also be tested by the vacuum decay method. Sensitivity data for flexible packages were not included in the precision and bias studies, although the use of vacuum decay for testing such packages is well known.
1.3 Test Results—Test results are qualitative (Accept/Reject). Acceptance criteria are established by comparing quantitative baseline vacuum decay measurements obtained from control, non-leaking packages to measurements obtained using leaking packages, and to measurements obtained with the introduction of simulated leaks using a calibrated gas flow meter.
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 and health practices and determine the applicability of regulatory limitations prior to use.
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Standard Terminology of Packaging and Distribution Environments |
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Standard Terminology Relating to Primary Barrier Packaging |
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Standard Practice for Conducting an Interlaboratory Study to Determine the Precision of a Test Method |
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Standard Terminology Relating to Barrier Materials for Medical Packaging (Withdrawn 2007) |
