A leak detection system for detecting leaks in pressurized containers, the system comprising a leak test conveyor for moving each container and an accumulation tunnel through which the leak test conveyer extends, wherein the accumulation tunnel and the leak test conveyer together define at least one enclosed accumulation volume, each enclosed accumulation volume being sized to accommodate only a single container, thereby to allow gas leaking from the single container to accumulate, and a gas sensor for sensing accumulated leaked gas from the single container.

A method and system is disclosed for determining the integrity of a closed container. The method and system includes the steps of positioning the container in a surrounding, changing a gas pressure, a gas composition, a gas concentration, or any combination of gas pressure, gas concentration and gas composition, in the surrounding. Thereafter subjecting the container to an optical sensor, non-intrusively, the sensor being sensitive to at least one gas, and the sensor is configured for detecting the at least one gas inside the container. Reading a signal from the optical sensor related to a gas pressure, a gas concentration, a gas composition, or any combination of gas pressure, gas concentration, and gas composition, inside the container. The behaviour of the signal being indicative of breach in integrity of the container.

An apparatus and methods for testing the integrity of a barrier coating on a vessel. An off gas test fixture includes a face seal positioned about an opening of the vessel. A side seal is positioned about a portion of the vessel's wall and separated from the face seal by a space. Additionally, a cover may be secured to the fixture that encompasses an interface portion of the fixture and the vessel. Before and/or during testing, gas in the space between the side and face seals may be evacuated, as well as gas present in an interior area of the vessel. The vessel may be exposed to test gas(es) that is soluble by the plastic material of the vessel before and/or after being secured to the fixture. During testing, test gas(es) desorbed by the vessel may be evacuated, with the molecular flow being measured using a mass extraction unit.

An inspection device and method for testing and inspecting integrity of a container (200) is disclosed. The inspection device has an angled member (102) and a viewing member (104) secured to the angled member. Together, the angled and viewing members are configured to hold a container to be analyzed. The inspection device also includes a cradle (106) secured to the angled member, the cradle including a cavity (108) configured to hold the angled member at an angle. The inspection device also includes a light source holder (110) secured to the viewing member, a leg member (112) extending from the light source holder, and at least one light source (114) extending through the light source holder. The light source has a first end extending outwardly from the light source holder and a second end extending within the light source holder from which light projects. The light from the light source is projected toward the viewing member. The viewing member includes at least one viewing window (105). A lens is located between the second end of the light source and the viewing member, and a filter is located between the lens and the viewing member.

For detected smallest leak in closed containers, which are at least to a part filled with a gas, the container (1) is pressurized by a test gas (g(s)) for an amount of time. The test gas (g(s)) comprises a gas species (s). The amount of the addressed gas species (s) which has penetrated in the container 1 it is sensed (7) as a leak indication.

A method for leak testing a test specimen includes the following steps: placing the test specimen in a test chamber, testing a leak-tightness of the test specimen in the test chamber, opening the test chamber and removing the test specimen if the leak test has determined that the test specimen is leak-tight, and blocking the test chamber from opening to prevent a removal of the test specimen if the leak test has determined a leak in the test specimen. A leak testing device includes a test chamber receiving the test specimen, a leak detector connected to the test chamber, and a blocking device.

In leak testing by an accumulation method, it is possible to reliably detect accumulated inspection gas, and the reliability of leak testing is enhanced by reduction in background or impurity gas. At least an openable/closeable part 29 of a capsule 20 is housed inside a chamber 10 of a leak testing apparatus 1. A test workpiece 9 is housed in the capsule 20. Gas inside the chamber 10 is evacuated by a vacuum pump 31. A detector 2 detects inspection gas contained in this gas. The capsule 20 is continuously sealed for an accumulation time Ta, the capsule 20 is thereafter opened, and a leak is evaluated on the basis of detection information after the opening by the detector 2.

A method for conducting an integrity test on a flexible test container (1) includes arranging the test container (1) in an examination container (5) that is sealable in a fluid-tight manner, providing negative pressure in the interior of the sealed examination container (5), filling examination fluid into the test container (1) arranged in the examination container (5), detecting examination fluid present in the interior of the examination container (5), and providing negative pressure in the test container (1) arranged in the examination container (5) prior to filling examination fluid being. The negative pressure in the test container (1) is lower than the negative pressure in the interior of the examination container (5), and the pressure difference between the negative pressure in the test container (1) and the negative pressure in the interior of the sealed examination container (5) is more than 0 mbar and a maximum of 100 mbar.

A method for helium mass spectrometric fine-leak test is based on quantitative determination of maximum test-waiting time, which gives a method for quantitative determination of the maximum test-waiting time for fine-leak test during a helium mass spectrometric test process of the sealability, and gives a method for determining the criterion for measured leak rate by taking the minimum helium gas exchange time constant, i.e., a rigour grade .sub.Hemin, of an acceptable sealed electronic component as a basic criterion for helium mass spectrometric fine-leak test. Based on the inventive method for quantitative determination of the maximum test-waiting time, for most of the cavity volume ranges, the maximum test-waiting time that is determined accurately may be much longer than 1 hour or 0.5 hour as determined qualitatively by the existing related standards.

Inspecting and/or testing of inline conveyed devices is performed in that a monitoring unit is applied to a device. The monitoring unit is removed in a removing area. Within the timespan the monitoring unit is applied to the device, the monitoring unit is operated in a standalone operating mode. During a timespan information about the device to which the monitoring unit is applied is collected in the monitoring unit. This timespan of collecting includes at least a part of the timespan during which the monitoring unit is operated in standalone mode.