DE29723573U1 - Pressure tester - Google Patents

Description

Wolfgang Rausch
GmbH & Co.

88138 Weißensberg near Lindau RA 97350 GM

Pressure tester

The invention relates to a pressure testing device for internal testing of the tightness of pipes, in particular of socket connections of pipes, with two inflatable ring-shaped sealing cushions which are connected to a compressed air source via a first compressed air line and are attached to an essentially tubular device body at an axial distance from one another, whereby in the inflated state, resting against the inner wall of the pipe, they delimit an annular test chamber between the inner wall of the pipe and the tubular device body, whereby a second pressure medium line also leads into the test chamber and an overpressure in the test chamber can be detected by a pressure sensor.

Such a pressure testing device is known from US 3,400,574. The pressure testing device is a carriage that contains a tube with wheels that forms a central flow channel so that the pressure testing device can carry out pressure tests in a pipeline while the pipeline continues to operate. A camera is permanently installed in the front end area of the pressure testing device, which monitors the interior of the pipeline in front of the respective test area so that obstacles can be identified that the testing device could get stuck on. The pressure testing device is pulled through the pipeline using a winch.

Such a pressure tester is expensive and it is difficult to position the device precisely when, for example, socket connections of pipes are to be checked for leaks, since the built-in camera can only view the area in front of the pressure tester.

The present invention is based on the object of further developing a pressure testing device of the type in question so that it can be manufactured at lower cost and that its exact positioning at a point of a pipeline to be examined, in particular a socket connection, is considerably facilitated.

This object is achieved according to the invention by the features of patent claim 1.

Advantageous embodiments of the invention are characterized in the subclaims.

In the pressure testing device according to the invention, the essentially tubular device body consists of a tube made of a transparent material at least in the area between the sealing cushions, and the pressure testing device can be coupled to a camera carriage in such a way that a pivoting camera of the camera carriage is arranged inside the transparent tube and aligned in such a way that it covers the area of the inner wall of the pipe to be examined.

The pressure testing device according to the invention is therefore a relatively simple additional device that can be used together with a camera carriage that is usually already available and can be used for numerous other purposes, so that a conventional, expensive pressure testing system is no longer required for leak testing of pipes, especially socket connections. The transparent pipe, for example, consists of

made of acrylic glass, without the invention being limited thereto.

The camera located inside the transparent pipe, which is preferably a circular and swivel camera, can locate the pipe area to be tested, preferably a socket, whereupon the camera is then preferably swiveled to 90o. In this way, the pressure tester can be positioned exactly so that there is a sealing cushion or a sealing sleeve on both sides of the socket to be tested, which is then filled with compressed air. Since the pressure tester can be positioned exactly on the socket to be tested, the axial distance between the sealing cushions can be particularly small, which means that the test chamber has a small volume and can be filled with small amounts of the test medium, i.e. compressed air, in the shortest possible time.

In further details of the invention, it is proposed that the sealing cushions are seated in ring-shaped, cross-sectionally approximately U-shaped holders, which are attached to the side ends of the transparent tube. The transparent tube can, for example, be inserted into circumferential grooves of the holders and glued to them, without the invention being limited to this. It is important that the connection of the transparent tube to the holders is tight, since no pressure medium can escape here.

The first compressed air line, which supplies compressed air to the two sealing cushions, preferably flows into the two sealing cushions through the base wall of the brackets. The first compressed air line runs inside the transparent tube, which preferably also applies to the second compressed air line, which can flow into the test chamber through the transparent tube. Alternatively, this can also be led into the test chamber through the base body.

A line branches off from the second compressed air line and leads to the pressure sensor that measures the excess pressure in the test chamber. According to a further proposal of the invention, this pressure sensor is attached to the camera carriage so that the connecting line to the test chamber is short. This means that the pressure sensor can measure the excess pressure in the test chamber very precisely, since only a small volume of compressed air is measured in the short piece of hose.

During the measuring process, the second compressed air line before the branch point is preferably closed by means of an electromagnetic valve, since the connection to the compressed air source must of course be interrupted during the measuring process.

An electrical line leads from the pressure sensor to the display and evaluation electronics, which are preferably located in a vehicle above ground. The electrical line is advantageously arranged within a compressed air line, preferably within the second compressed air line. Alternatively, it is proposed to permanently connect the electrical line to a compressed air line, for example by gluing the electrical line to the outside of a compressed air line. The two compressed air lines are also permanently connected to one another.

These designs have the advantage that the two compressed air hoses and the electrical cable are unwound from or wound onto a single drum, which eliminates the need for the synchronization of several drums that would otherwise be necessary.

-5-

The pressure tester is preferably provided with wheels that are attached to the front end section of the pressure tester facing away from the camera inlet. Preferably, two wheels are attached that are at an angle to each other in the front view of the device. The wheels are preferably attached to support arms that protrude from the holder of the front sealing cushion in an axial direction. This means that the wheels are not located under the device, but in front of it, which makes it possible to arrange relatively large wheels that only have a small radial projection over the sealing cushions when they are unfilled. This means that the filling volume of the sealing sleeves is small, so that the filling and venting time is only short.

When in use, the pressure tester is conveniently screwed onto the camera carriage. For this purpose, the camera carriage can be provided with a cross member in the end area of its swivel arms that hold the camera, which is screwed onto the rear bracket of the rear sealing cushion.

Alternatively, the pressure tester can be coupled to the camera carriage via a detachable locking connection.

The pressure testing device according to the invention does not require a cable winch for use, which is why it can be positioned from the starting shaft and can also be used if only one side of the pipeline to be tested is accessible. The pressure testing device can be positioned precisely using the camera located inside it, whereby the entire testing process can be monitored with the camera. This also makes it possible to visually inspect a socket connection to be tested.

-6-

To supply the test device, a double hose with integrated control line is preferably provided so that only one hose reel is required.

The entire inspection period is short because the sealing sleeves and the test chamber have only a small volume.

A great advantage of the invention is that the pressure test device can be adapted to existing TV systems.

Further details of the invention emerge from the following description of an arrangement comprising a pressure testing device according to the invention and a conventional camera carriage as well as from the drawing. Showing:

Fig. 1 a vertical section through a pipe to be inspected

with an arrangement therein consisting of a
Pressure tester and a camera trolley and

Fig. 2 is a front view of the pressure testing device according to Fig. 1 from the left.

A pressure testing device, designated as a whole by 1, is positioned inside pipes 2 in such a way that it can subject their socket connection 3 to a pressure test. The pressure testing device 1 has a substantially tubular device body 4, which essentially consists of a plexiglass tube 5 and two ring-shaped holders 6, which are approximately U-shaped in cross section and are firmly connected to the plexiglass tube 5. For this purpose, the end sections of the plexiglass tube 5 are inserted, for example, into ring grooves in the holders 6 and glued therein.

-7-

Sealing pads 7 are located in the brackets 6 and are supported laterally by webs 8, 9 of the brackets 6. In the pressure-free state shown, the sealing pads 7 have only a relatively small distance to the inner wall 10 of the pipes 2.

A first compressed air hose 11, which is connected to a compressed air source at its end (not shown), opens into the sealing cushions 7 by leading with its end section 12 and a branch line 13 through the bottom walls 14 of the holders 6.

When compressed air is supplied to the sealing cushions 7, they expand radially and rest against the inner wall 10, thereby defining a test space 18 between the plexiglass tube 5 and the inner wall 10.

Compressed air is introduced into this test chamber 18 through a second compressed air hose 19, which opens into the test chamber 18 at 20. A line 15 branches off from the compressed air hose 19 in front of the pressure test device 1, which leads to a pressure sensor 16. In front of the branch line 15, there is an electromagnetic shut-off valve 17 in the compressed air hose 19 or the compressed air line 19.

If a predetermined overpressure prevails in the test chamber 18, this overpressure is measured over time by the pressure sensor 16, and the measured values are passed on via an electrical control line, preferably arranged inside the compressed air hose 19, to a display and evaluation electronics located above the ground. The two compressed air hoses 11 and 19 are firmly connected to one another to form a double hose up to the pressure test device 1, where they branch off.

-8th-

Two support arms 20 are screwed onto the front bracket 6, each of which holds a wheel 21 so that it can rotate. The wheels 21 are arranged at an angle to one another, as shown in Fig. 2. The support arms extend in the axial direction of the pressure tester 1, so that the wheels 21 are not located under, but in front of the pressure tester 1.

The pressure testing device is coupled to a conventional camera carriage 22, which holds a circular and swivel camera, designated overall with 24, with swivel arms 23. The camera 24 is located in the coupled state of the pressure testing device 1 with the camera carriage 22 inside the Plexiglas tube 5.

A support structure 25 is attached to the swivel arms 23 and is screwed to the web 8 of the rear bracket 6. This means that the pressure testing device 1 and the camera carriage 22 form a unit when moving through the pipes 2. The pressure sensor 16 is also attached to the support structure 25.

During the test of the socket connection 3, the camera 24 is pivoted by 90o from the position shown so that a visual inspection of the socket area can be carried out with the video camera during the test.

Claims (14)

Expectations 1. Pressure testing device for the internal testing of pipes, in particular socket connections of pipes, with two inflatable ring-shaped sealing cushions which are connected to a compressed air source via a first compressed air line and are attached to a device body at an axial distance from one another, wherein in the inflated state, resting against the inner wall of the pipe, they delimit an annular test chamber between the inner wall of the pipe and the tubular device body, wherein a second compressed air line also leads into the test chamber and an overpressure in the test chamber can be detected by a pressure sensor,
characterized, that the device body (4) has a pipe (5) made of a transparent material at least in the area between the sealing cushions (7) and that the pressure testing device (1) can be coupled to a camera carriage (22) in such a way that a pivotable camera (24) of the camera carriage (22) is arranged in the interior of the pipe (5) and can be pivoted in such a way that it is aligned with the area of the socket connection. 2. Pressure testing device according to claim 1, characterized in that the sealing cushions (7) are seated in annular, cross-sectionally U-shaped holders (6) which are attached to the lateral ends of the transparent tube (5). 3. Pressure testing device according to claim 1 or 2, characterized in that the first compressed air line (11) leads through the bottom wall (14) of the holders (6) into the two sealing cushions (7). -10- 4. Pressure testing device according to one of claims 1 to 3, characterized in that wheels (21) are attached to the front end of the pressure testing device (1) facing away from the inlet opening of the camera (24). 5. Pressure testing device according to claim 4, characterized in that the wheels (21) are attached to support arms (20) which project from the holder (6) of the front sealing cushion (7) in the axial direction. 6. Pressure testing device according to one of claims 1 to 5, characterized in that the second compressed air line (19) leads through the transparent tube (5) or through the base body into the test chamber (18). 7. Pressure testing device according to one of claims 1 to 6, characterized in that a line (15) branches off from the second compressed air line (19) to the pressure sensor (16). 8. Pressure testing device according to claim 7, characterized in that an electromagnetic valve (17) is arranged in the second compressed air line (19) before the branch of the line (15) leading to the pressure sensor (16). 9. Pressure testing device according to one of claims 1 to 8, characterized in that an electrical line leads from the pressure sensor (16) to a display and evaluation electronics. 10. Pressure testing device according to claim 9, characterized in that the electrical line is arranged within a compressed air line. 11. Pressure testing device according to claim 9, characterized in that the electrical line is permanently connected to a compressed air line. -11- 12. Pressure testing device according to one of claims 1 to 11, characterized in that the pressure sensor (16) is attached to the camera carriage (22). 13. Pressure testing device according to one of claims 1 to 12, characterized in that the pressure testing device (1) can be screwed onto the camera carriage (22). 14. Pressure testing device according to one of claims 1 to 12, characterized in that the pressure testing device is coupled to the camera carriage via a detachable locking connection.