DE2816687A1 - Testing integrity of hollow article - involves using leak detection procedure by placing article in sealed test chamber - Google Patents

Abstract

The integrity of a hollow article (12) having an opening (22) is tested by a leak detection procedure by placing the article in a sealed test chamber(1) with the opening (22) exposed. The chamber (1) are article (12) are then evacuated via valve(5) and the opening (22) sealed by operating closure device (13, 21) from outside the chamber. The evacuation is then continued of the space surrounding the article (or of the interior of the article) to produce a pressure differential across the article wall. A test gas (19) is then admitted to the high pressure region and a test gas detector (8) is connected to the lower pressure region.

Description

Method and device for inte-

gralen leak detection The invention relates to a method for integral Vacuum leak detection on test items such as containers, barrels or the like.

It is increasingly desirable to post containers of this type immediately to subject their production to a careful leak detection. The technical and The time required for this leak detection is greater, the greater the production capacity and the more sensitive the leak detection should be.

It is known that test specimens of the type mentioned can be applied integrally for leaks investigate. With integral leak detection, the test item is placed in a test chamber, then the test object and the test chamber are removed with the help of an evacuation system evacuated in such a way that a differential pressure arises on the walls of the test specimen; then test gas is let in on the side with the higher pressure and the one on the side with the lower pressure existing gases are then with the help of a test gas-sensitive detector examined.

A device for integral leak detection is e.g. from DT-OS 2 403 360 previously known. With this device are provided with a flange connection Test specimens first with their opening facing down on one of the evacuation of the test specimen serving line connected. Then a hood is put over the test item, so that a closed test chamber is created, which is connected via a further connection line is evacuated.

An integral leak detection process is then carried out on the test item performed.

This known device is for use in production plants with high production capacity completely unsuitable. Under high production capacity the production of a few containers per minute is to be understood here. Already flanging the container to be tested to the evacuation system would be a multiple need this time. There is also the opening of the test object with connection elements that reduce the pumping speed of the evacuation system is the time which is necessary to both the specimen and the interior of the test chamber to evacuate a given pressure, relatively large. There is also the risk of that with separate - albeit simultaneous - evacuation of the test object and the remaining contents of the test chamber a maximum differential pressure is exceeded, which the walls of the often made of plastic or thin steel sheets Test specimen not withstand. Such an exceeding of the permissible differential pressure would, for example, always take place if the test chamber is not tightly sealed.

Finally, the previously known device is not suitable for test objects, which are practically only roughly cylindrical, i.e. a relatively large one at the top and bottom Have opening. Such test items can be, for example, car rims or the like. These do not have any flange connections that can be connected to any lines.

The present invention is based on the object of a method to specify for integral leak detection, on the one hand fast cycle times and on the other hand the risk of exceeding a permissible differential pressure no longer exists. In addition, a technically simple device for implementation of the procedure. Ultimately, the device should be on for about cylindrical test specimens be suitably designed.

According to the invention, this object is achieved in that the test object is introduced openly into the test chamber that test chamber and test object together to be evacuated to a predetermined pressure, that then with the help of an outside the test chamber actuatable locking device that can be placed on the test specimen a vacuum-tight separation of the interior of the test object from the interior of the test chamber takes place and that the pressures necessary for the leak detection are then generated and subsequently the actual leak detection process is carried out.

With this method it is no longer necessary to test the test object before being introduced into the test chamber in a complex manner to an evacuation device to be flanged. After closing the test chamber, the opening of the container is not narrowed by connection devices, so that an optimally rapid evacuation of the test object is possible. Since the test item and test chamber are evacuated at the same time, there is no risk of the permissible differential pressure being exceeded. The fast one Evacuation of the test item and test chamber to relatively low pressures also has nor the advantage that high demands are placed on the sensitivity of the leak detection since the integral leak detection is more sensitive, the lower is the pressure level at which the leak detection is carried out.

A method of this type is particularly useful for leak detection with fast cycle times on approximately cylindrical test objects, e.g. car sets. In the case of such test items, it must only be ensured that the locking device opposite side of the test item, also closed during the leak detection will.

The test specimen can also expediently via the locking device a test gas source or a test gas detector can be connected.

Further advantageous procedural features are that for ventilation the test chamber and the test item after the actual leak detection process the differential pressure is compensated, then the connection between the interior of the test specimen and the interior of the test chamber and then both Rooms are ventilated at the same time. These measures again have the advantage that inadmissible excess differential pressure does not occur. In the event that that Test gas was let into the test item for the leakage process, is still present the advantage that when venting it is avoided that large amounts of test gas are released from the interior of the test specimen can get into the test chamber.

One suitable for carrying out the method according to the invention The device comprises, in a manner known per se, a test chamber, an evacuation system, a test gas source and a test gas detector and is also characterized by that one of the walls of the test chamber is at closed test chamber has externally operable closure device, the tight separation of the Serves interior of the test specimen from the interior of the test chamber. The locking device can be arranged at any point on the test chamber walls. It becomes functional arranged where after the transport of the test specimen into the test chamber the Opening of the test object is located. Furthermore, the closure device can be connected to the connection serve as a line to the interior of the test object. Finally, the closure device Openings of any size can be easily adapted to test objects.

If the test chamber consists of a base with a removable cover, then For example, the closure device can easily be arranged on the hood. the Movement of the hood is not hindered by this. Serves the locking device also the connection of a line to the interior of the test object (test gas inlet or Connection to the test gas detector), then this has a relatively small cross-section, so hindered the mobility of the hood only a little. Evacuation lines with large cross-section, which increases the flexibility of the hood; would seriously affect are conveniently connected to the solid floor of the test chamber.

The closure device expediently consists of a gas-tight duwslh The stamp passed through the estkammerwandung with a flange-like sealing element for attachment to the test item.

For test items with stable walls, the necessary Tightness can be generated by a certain contact pressure.

If the test object only has an approximately cylindrical wall, then it can this contact pressure is also used to close the second opening of the test object, which faces the bottom of the test chamber and which there is corresponding sealing means assigned. However, if the DUT has relatively unstable walls, then this is the The punch is expediently designed to be hollow and intended to accommodate a rod, with which locking means assigned to the sealing element can be actuated.

Further advantages and details of the invention will be based on FIG illustrated in Figures 1 to 3 schematically illustrated embodiments will. The figures show: FIG. 1 a section through one for carrying out the invention Device suitable for the process; Figure 2 is a section through the closure device FIG. 3 shows a device according to the invention which is suitable for test objects with approximately cylindrical Walls, that is to say with two opposing openings, are suitably designed is.

The embodiment of Figure 1 comprises a test chamber 1, the from a solid base 2 and one that can be placed on it in a vacuum-tight manner with the aid of the seal 3 4-hood is formed. The vacuum pump is at the bottom of the chamber via a valve 5 6 and, via a valve 7, the test gas detector 8 shown schematically as a block closed. In addition, 2 is through the floor a rotatable one Shaft 9 passed through tightly, on the inside of the test chamber 1 a plate 10 with ribs 11 for placing the test piece 12 on. The ribs allow that the integral leak detection process also affects the bottom surface of the test item 12 extends.

In the upper wall of the hood 4, that according to the invention is general with 13 designated locking device is provided.

This consists of a vacuum-tight 4-way through with the help of the seal the hood wall passed through punch 15 and one of a piston 16 and a cylinder 17 existing actuator. On the hollow ones The stamp 15 is, via a valve 18, the test gas source shown schematically as a block 19 connected. In addition, in the exemplary embodiment then presented A compressed gas source 20a (for test gas-free gas) is connected via the valve 20.

At its lower end, the punch 15 carries a flange-like sealing element 21 mm is the opening 22 of the test specimen 12 opposite the contents of the test chamber 1 can be closed.

At the same time, a connection of the interior of the test object is then established 12 with the lines leading to the test gas source 19 or compressed gas source 20a.

With the device shown, the integral leak detection can be carried out as follows be carried out: The test item 12 is in a manner not shown - expedient placed on the plate 10 with the aid of automatically operating transport devices and then the hood 4 is placed over the test object 12 to form the test chamber. Of the Stamp 15 is in its upper position. The valves 5, 7, 18 and 20 are closed. Immediately after the test chamber is closed the valve 5 is opened, so that the test specimen 12 and the test chamber 1 simultaneously to be evacuated.

During this time - if necessary - by turning the plate 10 an assignment of the opening 22 of the test object 12 to the closure device 13 or to the sealing element 21 are made. Is the pressure level in the interior of the test object reached, at which test gas is to be admitted, the ram 15 moves downwards and thus separates the interior of the test object 12 from the remaining interior of the Test chamber 1. The valve 5 is then left open for the time necessary is to generate the vacuum necessary for leak detection in the test chamber. Thereafter the valve 5 is closed and the valve 18 for the inlet of test gas into the test specimen 12 open.

At the same time, through the valve 20 compressed gas up to the required Test differential pressure are admitted. This pressurized gas can increase further the differential pressure and the saving of test gas. After these procedural steps the valve 7 is opened and the test gas detector 8 is switched on as a result. Is in the Container 12 there is a leak, then test gas penetrates into the test chamber 1 and is registered by the detector 8.

In the example embodiment described, the integral leak detection is carried out on the walls of the test item 12 from the inside to the outside. This can also be done the other way round be carried out by detector 8 and test or compressed gas source 19 or 20a be swapped. The leak detection is then carried out in such a way that test chamber 1 and Test item 12 together in the manner described except for the required pressure to be evacuated. After that, the Test item 12 with the help of the stamp 15 closed and in the test chamber to generate the necessary differential pressure Test and pressurized gas admitted. With the help of the hollow stamp in this case 15 connected test gas detector 8 is then carried out the leak test.

In the figure 2 is an embodiment of the closure device according to the invention 13 is shown enlarged again, namely in the position in which the sealing element 21 is placed on the test tube T 12 with the opening 22. From there is a viewing hole that the punch 15 with the aid of the pneumatically actuated cylinder piston device (16,17) can be moved up and down.

The punch 15 is hollow and opens into the interior of the container 12. About the connection piece 23 can therefore -depending on how the leak detection process takes place - the supply of test gas and possibly compressed gas or the connection of the Test gas detector. In the punch 15, the rod 24 is housed, which is on at its upper end the also pneumatically operated cylinder piston device 25, 26 is assigned, so that the rod 24 can be moved up and down relative to the punch 15 is.

With its lower end, the rod 24 stands with several at its upper End pivotably mounted about the axis 30, hook-shaped levers 27 on their have lower side outwardly directed portions 28. By spring pressure (the Springs are not shown) these levers are in the position shown held when the rod 24 is in its upper position. Emotional the rod 24 downwards, then the lower end of the rod 24 presses on the inner projections 29 on the levers 27 and presses the levers 27 outward so that the sections 28 lie from below against the wall of the test object 12 and thereby generate the contact pressure necessary for sealing the sealing element 21. the The seal is designed as a double seal with the two sealing rings 31 and 32, which are arranged in grooves on the sealing element 21.

The sealing of the punch 15 with respect to the hood 4 is also a double seal educated. The sealing rings 14a and 14b form a chamber 34 which extends over the connecting piece 35 can be evacuated. Such a double seal with intermediate suction is special effective. Furthermore, the punch 15 itself also has a double wall, as a result of which the chamber 36 is formed. This stands over an opening 37 in the sealing element 21 with the space 39 formed by the sealing rings 31 and 32 in connection. Also is in the outer wall of the punch 15 located in the region of the chamber 34, the Opening 38 is provided.

These openings 37 and 38 cause the closure of the opening 22 serving seal has an intermediate suction and thus particularly effective is.

The lower end of the punch 15 also has a centering connection 40 which protrudes into the opening 22 when it is placed on the test object 12. The slots 41 through which the levers 27 reach are provided in this connecting piece.

The device shown in Figure 3 is for leak detection on car rims suitable. These have an approximately cylindrical shape so that not only the upper opening 22 with the help of the flange-like sealing element 21 but also the lower opening 42 must be closed before the leak detection. In addition is in the bottom 2 a relatively wide (to adapt to several rim sizes) sealing ring 43 provided to which the lower edge of the rim 12 adfimegt. A correspondingly wider one Sealing ring 44 is also provided in the flange-like sealing element 21. With the aid of the cylinder-piston device, which is not shown in detail in detail 16,17 the sealing element 21 is pressed via the punch 15 onto the rim 12, whereby a separation of the interior of the rim from the exterior is effected. The vacuum pump 6 and the test gas detection device 8 are connected to the interior through an opening 45 in the base 2 connected to the rim. The supply of test gas takes place in the from the hood and the rim limited outer space via a correspondingly arranged opening 46 in the Bottom 2. Finally, the bottom 2 also has one in the interior of the rim 12 protruding molded body 47, which significantly reduces the existing dead space, which enables faster evacuation and thus faster leak detection.

In the illustrated embodiment, the cylinder-piston device Mounted on the hood 4 via a connecting piece 48. In this connection piece 48 opens into a connecting line 49 through which flushing gas is blown in after the leak detection has been carried out to remove the remaining test gas residues.

These could falsify the immediately subsequent leak search.

The leak search is carried out in the manner described for FIG. First, after introducing the test item and putting on the hood 4 on the floor 2 with the sealing element 21 raised, evacuation of the interior space the hood.

Then the sealing element 21 is placed on the upper edge of the rim, so that two separate rooms are created by the wall to be examined Rim are separated. These steps are followed by the actual leak detection the manner already described, in that relatively wide sealing rings 43 and 44 are present and that the path of the sealing element 21 is relatively large, is the Device for rims of different heights and widths or others Test specimens with roughly cylindrical walls are suitable.

Claims (19)

CLAIMS Procedure for integral vacuum leak detection on test objects, such as containers, barrels or the like, in which the test specimen is placed in a test chamber is, then the test object and the test chamber with the help of an evacuation system in such a way evacuated so that a differential pressure is created on the walls of the test object, then test gas is admitted to the side with the higher pressure and the the side with the lower pressure with the help of a test gas sensitive Detector are examined, characterized in that the test item (12) is open is introduced into the test chamber (1) that test chamber and test object together up to evacuated to a predetermined pressure, then with the help of an outside the test chamber actuatable locking device (13) that can be placed on the test specimen a vacuum-tight separation of the interior of the test object from the interior of the test chamber takes place, and that then the pressures necessary for the leak detection are generated and subsequently the actual leak detection process is carried out. 2. The method according to claim 1, characterized by using the from outside the test chamber actuatable, can be placed on the test specimen closure device (13) both a vacuum-tight separation of the interior of the test object from the interior the test chamber and the connection of the test item to a test gas source (19) or to the test gas detector (8). 3. The method according to claim 1 or 2, characterized in that for Ventilation of test chamber (1) and test item (12) after the leak detection process the differential pressure is compensated, then the connection between the interior of the test specimen and the interior of the test chamber and then both Rooms are ventilated at the same time. 4. Apparatus for performing the method according to claim 1, 2 or 3, characterized in that it has a test chamber (1), an evacuation system (6), a test gas source (19) and a test gas detector (8) and that one of the walls of the test chamber comprises a closed test chamber has externally operable closure device (13), the tight separation of the interior of the test object from the interior of the test chamber is used. 5. Apparatus according to claim 4, characterized in that the closure device (13) is also used to connect a line to the interior of the test object (12). 6. Apparatus according to claim 4 or 5, characterized in that the test chamber (1) is formed by a base (2) with a removable hood (4) and that the closure device (13) is arranged in the hood. 7. Apparatus according to claim 6, characterized in that on the ground (2) the test chamber (1) the evacuation system (6) is connected. 8. Device according to Asn claim 7, characterized in that on the ground (2) the test chamber (1) a connection for the test gas inlet is provided and that the closure device (13) provided in the hood with the test gas detector (8) connected is. 9. Apparatus according to claim 7, characterized in that on the ground (2) the test chamber (1) the test gas detector (8) is connected and that the in the connection device (13) located on the hood is connected to the test gas source (19) is. 10.Vorrichtung according to claim 9, characterized in that the closure device (13) also connected to a storage container (20a) for test gas-free compressed gas is. 11.Vorrichtung according to any one of claims 4 to 10, characterized in that that the closure device (13) passed a gas-tight through the test chamber wall Stamp (15) with a flange-like sealing element (21) for attachment to the test item (12). 12.Vorrichtung according to claim 11, characterized in that the stamp (15) is hollow and that therein a linkage (24) for the sealing element (21) associated locking means (27 to 30) is housed. 13. The apparatus according to claim 12, characterized in that the Locking means (27 to 30) with the help of the rod (24). have levers (27) which can be introduced into the opening (22) of the test object (12). 14. Device according to one of claims 4 to 13, characterized in that that for sealing the stamp (15) against the hood (4) and / or for sealing of the sealing element on the test item (12) a double seal with intermediate suction are provided. 15.Vorrichtung according to claim 14, characterized in that the stamp (15) is double-walled and that over the one formed by the double wall Space (36) the intermediate suction takes place. 16.Vorrichtung according to any one of the preceding claims, characterized in that that the bottom of the test chamber sealant for vacuum-tight closure of the second Has side of an approximately cylindrical test object. 17.Vorrichtung according to claim 16, characterized in that the sealing means consist of a sealing ring embedded in the base of the test object. 18.Vorrichtung according to claim 16 or 17, characterized in that the Bottom (2) a shaped body (47) protruding into the cylindrical test specimen (12) having 19.Vorrichtung according to any one of the preceding claims, characterized in that that the closure device or the hood with a connection line (49) for the Supply of a purge gas is connected.