It is an object of the present invention to provide same results of leak judgments even if conditions such as temperature and pressure vary as long as sizes of sealing defects are same. A leak device 5 that generates regular leakage under regular temperature and pressure is made communicable with a test path 19 through which a test pressure is provided. A device actual measurement leak value of the leak device 5 is actually measured by a leakage measuring instrument 33. An object actual measurement leak value of a test object 9 is actually measured by the leakage measuring instrument 33. The object actual measurement leak value is converted into a regular-conditions-converted leak value based on the device actual measurement leak value and a leakage is judged based on the regular-conditions-converted leak value.

A tube sealing positioning apparatus has a tube holder slidable on a vertical guide from a lower to an upper portion of a sealing chamber for positioning adjacent a heating apparatus and a clamping apparatus. The heating apparatus may have a nozzle to direct heated air on an open end of a plastic tube. The clamping apparatus may have two clamping devices slidably disposed to clamp the heated open end of the plastic tube to fuse the tube wall adjacent the open end. A control processor may be connected to control movement and dwell time of the tube holder, and to control heat application and clamp spacing and time. A sealed tube may be attached to a top cover to be positioned in a test container. A sealing disk may close the top cover and may direct fluid pressure into the tube and apply a vacuum to the test container.

A method for testing a container (11) having an interior volume (12) for tightness, comprising the following steps: providing the container (11) in a pressure chamber (10) and reducing pressure within the pressure chamber (10) or increasing pressure within the container (11) as far as a predefined test pressure, ascertaining a pressure profile (100) within the pressure chamber (10) over time, comparing the pressure profile (100) to a reference profile (200) in order to determine whether a leak is present within the container (11), wherein ambient conditions of the container (11) and/or the pressure chamber (10) are monitored and the reference profile (200) is adapted to changing ambient conditions.

The invention relates to a testing device for testing the tightness of containers (2), comprising a supply unit (3) for supplying the containers (2), a testing unit (4) for testing the tightness of the containers (2), a diverting unit (5) for diverting tested tight containers (2), and a discharge unit (6) for discharging containers (2) tested to be untight in the testing unit (2). The testing unit (4) has at least one individual testing chamber (42) for testing individual containers and at least one multiple testing chamber (41) for receiving a plurality of containers in order to simultaneously test multiple containers (2). The testing device also comprises a control unit (10) which is designed to supply possibly untight containers (2) which have been discharged by means of the discharge unit (6) from a multiple testing chamber (41) individually back into an individual testing chamber (42) in order to carry out an individual test of said containers.

The invention relates to a testing device for checking the leak tightness of containers (5), comprising a holding unit (3) for holding at least one container (5), which holding unit has a first holding part (31) and a second holding part (32), wherein the holding unit (3) is divided into the first and second holding parts (31, 32) in the direction of a longitudinal axis (L) of the holding unit (3) and wherein a pivot shaft (4) for the pivoting of at least one holding part is arranged on the first and/or second holding part (31, 32).

A coarse-fine two-stage leak detection is carried out on sealed, filled containers loaded into container holders or pucks. Failure of the first, coarse leak detection stage, e.g. a pressure-course or impedance or laser-absorption based leak detection stage, causes containers to be rejected together with their corresponding container holders. These are then separated, and the container holder is cleaned and dried before being returned to the system. Any leaking product from inside a grossly leaking container is thus retained within the container holder, thus reducing contamination of subsequent containers and their container holders, preventing such contamination from reaching the fine leak detection stage, e.g. a mass-spectrometer-based leak detection stage.

The present invention provides an air tightness detection device for an aluminum alloy wheel hub, which is characterized by precision air pressure sensors, a lower clamp, a cone cylinder pressure plate, air pipes, a pressure plate, guide posts, an air inlet pipe, and a compressed gas control and detection system. A technical solution of the present invention has the following advantages that the cone cylinder pressure plate of the detection device reduces the space of an inner cavity of the wheel hub to further reduce inflating volume, thereby increasing detection efficiency; the characteristics of readily availability for preparation, no pollution and low cost are achieved by taking compressed air as a leakage indication gas.

The invention relates to an adapter part (9) for connecting a medical hollow body (11) to a tension/compression measuring device (3), comprising a first connecting end (13), which is designed to connect the adapter part (9) to an interior (15) of a medical hollow body (11) in a fluid-tight manner, and comprising a second connecting end (17), which has a pressure chamber (19) and is designed to operatively connect the adapter part (9) to a tension/compression measuring device (3), so that a pressure in the pressure chamber (19) can be adjusted by means of the tension/compression measuring device (3), a hollow channel (21) passing through the adapter part (9) from the pressure chamber (19) to the first connecting end (13).

Disclosed herein is a gas fitting pressure test device in one example having a test plate with a first side configured to seal to a gas fitting. The gas fitting having a surface defining a void therein. The test device also having a gas conduit through the first side of the test plate, the gas conduit configured to be in fluid communication with an inner void of the gas fitting. The test device also having an electromagnet adjacent the second side of the test plate, configured to provide magnetic force on the gas fitting greater than the force exerted on the gas fitting. The test device having or connected to a source of positive gas pressure in fluid communication with the gas conduit.

A close-type speaker leak test system includes a first chamber, a second chamber, a third chamber, a fourth chamber, a vacuum generator, and a differential pressure gauge. Firstly, a negative pressure value of the first chamber and the second chamber is generated by the vacuum generator. A standard close-type speaker is placed within the third chamber, and the first chamber and the third chamber are in communication with each other. An under-test close-type speaker is placed within a fourth chamber, and the second chamber and the fourth chamber are in communication with each other. A pressure difference value between the third chamber and the fourth chamber is measured by the differential pressure gauge. If the pressure difference value is larger than a predetermined value, the under-test close-type speaker has the leak. Consequently, the misjudgment is reduced, and the testing efficiency is enhanced.