DE102012109433B4 - Method for pressure and vacuum testing of piping systems for leaks - Google Patents

Abstract

Method for checking the tightness of piping systems (1), based on an examination of the resistance of the internal pressure prevailing inside the piping system (1) to a different external pressure surrounding the piping system (1), characterized in that the possibility of Misslingens the tightness test due to a clogging of leaks in the conduit system is reduced by vibrations transmitted by at least one vibrator (24) at least one point of the piping system (1).

Description

Technical area

The invention relates to a method for pressure and vacuum testing of piping systems for leakproofness according to the preamble of patent claim 1.

State of the art

1. (1) Leckagen durch Korrosion,
2. (2) undichte Stellen an Muffen, z.B. durch unkorrekte Verschraubungen oder fehlerhafte Teile,
3. (3) Haarrisse in den Rohrleitungswänden,
4. (4) Beschädigungen durch mechanische Einwirkungen.

On piping systems, leaks often occur, eg of the following type:

1. (1) leaks due to corrosion,
2. (2) leaks on sleeves, eg due to incorrect screw connections or faulty parts,
3. (3) hairline cracks in the pipeline walls,
4. (4) Damage due to mechanical effects.

Domestic water piping systems are e.g. according to ZVSHK- and BHKS-Merkblatt 5.001 (2004) after plant dewatering with the aid of compressed air at (for example 3 bar) or forming gases or also according to DIN 1988-2 with the help of drinking water (at for example 15 bar) tested for leaks. If this pressure falls again after its generation, the leakage of the pipe system has been proven. The tightness tests are also carried out with negative pressure.

In addition, sewer TV cameras are used to clean sewer pipes, with the help of which optically visible leaks can be detected.

Out DE 195 42 890 C1 is known a method for detecting leaks in fluid-carrying pipelines. In this case, a pressure change is generated in the fluid and the time course of the pressure change measured at different locations of the pipeline. The differences in the time course of the pressure change at the various locations give indications of the leak rate and the leak location. Furthermore, there is described a leak detection method of the same type, in which a pressure wave front is generated in a tightly sealed pipe section to form a vibration of the fluid column and compared with a simulation model for different parameter values of leak rate and leak location calculated pressure curves with a measured pressure profile.

DE 26 28 178 A1 describes automatic and continuous quality control of pipes by exciting the pipe to a resonant frequency vibration that is measured.

DE 28 09 540 A1 concerns the detection of pipe leaks by equipment carried in the material flow in the pipeline for the purpose of investigating acoustic signals caused by leaks or external sources of vibration.

JP 2001-021 100 A addresses the problem of ignoring a single audible signal when testing a pipe.

Disadvantages of the prior art

The method of line testing using positive or negative pressure has significant disadvantages. This is because the leak test does not provide the correct result if an existing leak is clogged by particles or contaminants and the piping system therefore appears to be tight. Such soiling can often not be eliminated by a temporarily generated pressure or negative pressure.

When testing the piping system then their tightness is detected, although in fact there is a leak that is only temporarily clogged. The test can not be carried out with the right result - the leak tester has to repack his test equipment after his unsuccessful attempt and drive home without having to do so. When the presence of a leak can be successfully detected is uncertain.

Another disadvantage of the prior art is that so far because of the possibility of clogged leaks, the usability of older pipe systems can not be objectively clarified. At present, it is only possible to judge the leakproofness of a pipeline system by its obvious impression. Therefore, it is not yet possible to determine whether a pipeline system will be reliably leak-proof in the near future.

Although there are methods for eliminating deposits in water pipes by pressure pulses Also in this process is ultimately pressure, which, as described often has the consequence that the particles are pressed even more strongly into the leak, so that the leak continues remains hidden.

The channel TV cameras used to clean sewer pipes in most cases do not help, because many leaks - especially smaller ones - are not visible.

Although the procedure in DE 195 42 890 C1 With pressure changes, there is also a risk that a leak can not be detected because it is clogged at the time of the pipe system test. As already stated above, a temporarily generated pressure or vacuum often can not eliminate blockages of a leak. The same applies to the leak detection method with pressure wave front described there.

Also in DE 26 28 178 A1 described quality control of pipes using resonant frequency vibrations leaves the problem of the measuring process affecting temporary obstruction of pipe leaks unresolved. In addition, this method only relates to the testing of individual pipes and not to the testing of pipe systems, so that it is not possible to test for leaks between individual pipes or at the joints of two pipes. Also, for example, adapter pieces and other short and thus non-oscillatory parts of the pipe system and their joints can be tested with this method.

By DE 28 09 540 A1 Known examination of acoustic leaks in pipes also works only as long as the leaks are not clogged during the test, so there is no solution to temporarily clogged leaks.

There JP 2001-021 100 A The problem of neglecting an acoustic signal occurring only once in the inspection of a pipe, is also not solved by this technical teaching, the problem of temporarily clogged leak.

task

The invention therefore has the task of ensuring that the leaks are not clogged by particles during the pressure or vacuum test.

solution

This object is achieved by the invention presented here.

The invention will be explained in addition to its individual embodiments and embodiments with reference to the drawings.

The implementation of this method for pressure and vacuum testing of piping systems for leaks is possible with the designated in the figures and embodiments technical equipment.

The invention will be described by way of reference numerals for ease of technical understanding, also in the description of the claims with reference to the drawings.

In the following description, the term "internal pressure" in the piping system ( 1 ) pressure, that is the pressure of the fluid (liquid or gas) in the piping system ( 1 ) is located.

"External pressure" refers to the pressure in which the piping system ( 1 ) surrounding fluid prevails.

Claim 1 - vibration at deviating pipe internal pressure

Claim 1 relates according to its preamble leakage tests on a pipeline system ( 1 ), which are measured by measuring an internal pressure different from the external pressure by checking whether the - usually artificially generated - internal pressure remains constant or changes, with a pressure change indicating a leak.

The internal pressure can be so far compared to the external pressure both an overpressure and a negative pressure. The surrounding external pressure need not necessarily be the atmospheric pressure, but is also in question that a pipe passes through a compressed air chamber or a vacuum chamber.

According to the characterizing part of claim 1, the risk of failure of the leak test due to temporary blockage of leaks in the conduit system is reduced by at least one vibrator (24) vibrations on at least one point of the piping system ( 1 ) be transmitted. In this way it is avoided that the leak test fails because a clogged leak remains undetected. Instead, particles that clog a leak are moved out of the line leak by the vibration. The tightness control is then no longer hindered by clogging particles.

The vibrator ( 24 ) can be used both before the production of the pressure difference and during the existing pressure difference.

1. a) ein einzelnes Leitungsrohr
2. b) ein Abschnitt eines Leitungsrohrs,
3. c) mehrere oder eine Vielzahl miteinander verbundener Leitungsrohre,
4. d) mehrere oder eine Vielzahl miteinander verbundener Leitungsrohre einschließlich pneumatisch oder hydraulisch daran angeschlossener Geräte,

wobei es sich bei dem Rohrleitungssystem (1) für die Dichtigkeitsprüfung um ein geschlossenes System handeln muss in der Weise, das abgesehen von eventuellen Leckagen pneumatisch bzw. hydraulisch sein muss, so dass eventuelle Entlüftungsöffnungen, Auslasshähne und ähnliche Öffnungen geschlossen werden müssen. Under a piping system ( 1 ) is understood here

1. a) a single conduit
2. b) a section of a conduit,
3. c) several or a plurality of interconnected conduits,
4. d) several or a plurality of interconnected conduits including pneumatically or hydraulically connected equipment,

whereby it is the piping system ( 1 ) must be a closed system for leak testing in such a way that, apart from any leaks, it must be pneumatic or hydraulic, so that any vents, outlet cocks and similar openings must be closed.

• - Rohrschellen,
• - Schraubklemmen,
• - Gummibändern,
• - Klebeverschlüssen

oder ähnlichen Befestigungsmitteln.The attachment of the vibrator ( 24 ) on the pipeline system ( 1 ) can be done using, for example

• - pipe clamps,
• - screw terminals,
• - elastic bands,
• - adhesive closures

or similar fasteners.

Design according to claim 2 - overpressure

In the embodiment according to claim 2, the pipe internal pressure deviating from the external pressure is a pipe inner pressure which is higher than the external pressure.

The overpressure can be achieved, for example, by means of a compressor ( 22 ) be generated.

The procedure with the aid of vibration in the pipeline system ( 1 ) can be particularly effective when particles from the outside clog the leak, but are too large to be replaced by a negative pressure in the conduit through the leak into the interior of the pipeline system ( 1 ) to be sucked.

The pressure is measured by a pressure gauge for the piping system ( 15 ). An external external pressure gauge ( 28 ) can be connected via a fluid connection to the external overpressure measuring system ( 10 ) are connected.

Design according to claim 3 - negative pressure

In the embodiment according to claim 3, the pipe internal pressure deviating from the external pressure is a pipe internal pressure reduced in relation to the external pressure.

In this case, by means of negative pressure brought about by vacuum generator, the particles that were pressed from the inside into the leak, for example as a result of an earlier pressure in the pipeline system, can be reduced by the negative pressure into the interior of the pipeline (FIG. 1 ) are sucked back.

1. (1) Venturidüse
2. (2) Vakuumpumpe - z.B. elektrisch

In this case, as a vacuum generator eg in question:

1. (1) Venturi nozzle
2. (2) Vacuum pump - eg electric

The leak test using vibration in the piping system ( 1 ) prevailing negative pressure can be particularly effective when particles from the inside clog the leak, but are too large to be pressed by an overpressure in the conduit to the outside through the leak.

The pressure is measured by a vacuum gauge for the piping system ( 14 ). In addition, an external vacuum gauge ( 27 ) via a fluid port on the test system for external vacuum gauge ( 9 ) are connected.

Arrangement according to claim 4 - pressure change

According to claim 4, at least one pressure change is made during the vibration. Because even reducing or increasing the pressure during vibration can help to remove particles from the leaks.

Design according to claim 5 - check valve

Claim 5 sees between the line system and the device, which causes the pressure difference, a check valve ( 25 ) to prevent inadvertent cancellation of the pressure difference produced by the escape of the fluid from the test system ( 3 ) leading fluid line ( 6 ).

This has the advantage that the compressor ( 22 ) must not be constantly in operation to maintain the pressure difference or on the piping system ( 1 ) must be connected. Above all, this is necessary, for example, when the compressor ( 22 ) after production of the negative pressure with a Venturi nozzle ( 7 ) in the pipeline system ( 1 ) is to be used elsewhere for generating the vibration - eg by pulling off the compressor ( 22 ) coming from the Venturi nozzle ( 7 ) for direct connection to the piping system ( 1 ) for vibration, cf. below.

Embodiment according to claim 6 - Venturi nozzle

According to claim 6, the negative pressure by means of a Venturi nozzle ( 7 ) generated. Because the Venturi nozzle ( 7 ) to generate the negative pressure compressed air, however, the generation of negative pressure in the piping system ( 1 ) and the use of the vibrator at least not at the same time, if only one compressor ( 22 ) is available and vibrator ( 24 ) and Venturi nozzle ( 7 ) must be operated with different compressed air pressure. Either a second compressor ( 22 ) or an electric vacuum pump 7 , see. below.

Arrangement according to claim 7 - Electric vacuum pump

According to claim 7, the negative pressure by an electric vacuum pump 7 generated. In contrast to the variant with the Venturi nozzle ( 7 ) has the advantage that vacuum and vibration can be operated simultaneously even if only one compressor ( 22 ) is available.

Embodiment according to claim 8 - vibrator with elastic band

According to claim 8, the vibrator ( 24 ) by means of an elastic band on the piping system ( 1 ) are attached.

For the purposes of this patent application, band is understood to mean both a flat band and one with a round or other cross-section.

It comes, for example, a so-called O-ring into consideration, which is placed by the leakage tester around the pipe and can be hooked to the two protruding fastening tabs of the vibrator. For different pipe thicknesses and vibrator sizes, the leak tester can carry various sized O-rings.

• - Die Befestigung des Vibrators (24) am Rohrleitungssystem (1) ist mit einem elastischen Band sehr handlich und zeitsparend.
• - Bei der Befestigung des Vibrators (24) am Rohrleitungssystem (1) kann dessen Gewicht durch Einstellung der Spannung des elastischen Bandes bzw. durch Wahl der passenden Größe des O-Rings auf zeitsparende Weise berücksichtig werden.
• - Durch eine nur lockere Befestigung des Vibrators (24) mit einem elastischen Band - bzw. bei Befestigung des Vibrators (24) bei geringer Spannung des elastischen Bandes - kann erreicht werden, dass der Vibrator (24) selbst sich im Rhythmus der Vibration jeweils kurzzeitig vom Rohr löst und durch das elastische Band sogleich wieder zum Rohr zurückgezogen wird, so dass sich durch den rhythmisch gegen das Rohrleitungssystem (1) schlagenden Vibrator (24) besondere Vibrationsfrequenzen erzeugen lassen. Dadurch können auch kleine Vibratoren (24) besonders effektiv arbeiten.

This has the following advantages:

• - The attachment of the vibrator ( 24 ) on the piping system ( 1 ) is very handy and time-saving with an elastic band.
• - When attaching the vibrator ( 24 ) on the piping system ( 1 ), its weight can be taken into account by adjusting the tension of the elastic band or by choosing the appropriate size of the O-ring in a time-saving manner.
• - By only loosely attaching the vibrator ( 24 ) with an elastic band - or when attaching the vibrator ( 24 ) at low tension of the elastic band - can be achieved that the vibrator ( 24 ) itself in the rhythm of the vibration in each case briefly detaches from the tube and is immediately pulled back to the pipe by the elastic band, so that by the rhythmic against the piping system ( 1 ) beating vibrator ( 24 ) can generate special vibration frequencies. This allows even small vibrators ( 24 ) work very effectively.

Embodiment according to claim 9 - pressure waveform record

According to claim 8, during the leak test in the pipeline system ( 1 ) occurring pressure changes using a measuring device and recorded.

As an external overpressure measuring device ( 28 ) and as an external vacuum gauge ( 27 ) can each be used a device that not only measures the pressure, but at the same time stores the measurement data or graphically holds or prints.

Configuration according to claim 10 - arrangement for leak testing

Claim 10 relates to an arrangement with which a leak test according to claim 1 on a piping system ( 1 ) based on an examination of the resistance of the interior of the pipeline system ( 1 ) prevailing internal pressure in a deviating the piping system ( 1 ) surrounding external pressure can be performed.

1. a) ein Gerät zur Herbeiführung einer Druckveränderung ((7), (8), (22)), anschließbar am Rohrleitungssystem (1) über einen Fluid-Anschluss des Rohrleitungssystems (2),
2. b) ein Manometer ((14), (15), (16)) zur Messung des im Rohrleitungssystem (1) bestehenden Drucks, anschließbar z.B. am Rohrleitungssystem (1) oder an einer zum Rohrleitungssystem (1) führenden Leitung,
3. c) einen Vibrator (24), zu befestigen am Rohrleitungssystem (1).

The arrangement has in this case:

1. a) a device for causing a pressure change (( 7 ) 8th ) 22 )), connectable to the piping system ( 1 ) via a fluid connection of the pipeline system ( 2 )
2. b) a pressure gauge (( 14 ) 15 ) 16 )) for measuring the piping system ( 1 ) existing pressure, can be connected, for example, to the piping system ( 1 ) or at one to the piping system ( 1 ) leading line,
3. c) a vibrator ( 24 ), to attach to the piping system ( 1 ).

By means of this arrangement, the possibility of failure of the leak test due to clogging of leaks in the conduit system can be reduced by actuating the piping system (Fig. 1 ) acting vibrator ( 24 ) Vibrations on the piping system ( 1 ) by the clogging particles from the leaks in the pipeline system ( 1 ) can be removed.

As a device for causing a pressure change (( 7 ) 8th ) 22 )) comes into question: a Venturi nozzle ( 7 ), an electric vacuum pump ( 8th ), a compressor ( 22 ).

As pressure gauge (( 14 ) 15 ) 16 )), a vacuum gauge, an overpressure manometer or a pressure gauge is conceivable here, with which one can measure both overpressure and negative pressure.

For further details, reference is made to the corresponding description of the method claims.

Further advantages of the invention

Prevention of unexpected leaks

Another advantage of this method for pressure and vacuum testing of piping systems for leaks is that it can not only be used to check the tightness, but also for the prevention of surprising leaks can be used. Because after the leak test, the hitherto hidden leaks are unmasked as such and can be eliminated. Thereafter, it can be predicted with high probability that there will be no leaks in the near future due to leak-releasing particles and thus to damage from escaping substrates or to business interruptions.

This advantage comes mainly from older piping systems ( 1 ), whose usability has so far not been objectively clarified. So far, it has been possible to focus only on the apparent impression, which is insufficient for the expert and also for the measuring technician.

use Examples

1. a) Stahlrohre
2. b) Kupferrohre
3. c) Kunststoffrohre
4. d) Mehrschicht-Verbundrohre

The present invention can be used with regard to all protection claims for all types of lines, in particular for:

1. a) Steel pipes
2. b) copper pipes
3. c) plastic pipes
4. d) multilayer composite pipes

The invention can also be used for piping systems in larger building services complexes, such as in hospitals, factories etc.

1. a) Frischwasserleitungen
2. b) Abwasserleitungen einschließlich Rohrleitungen (1) in Kläranlagen
3. c) Gasleitungen
4. d) Heizungsrohre, insbesondere auch für Fußbodenheizungen
5. e) Absorberrohre und Rohre für die Weiterleitung des Wärmetransportmediums (flüssig oder gasförmig) für thermische Solaranlagen
6. f) Rohrleitungen für Getränke und deren Komponenten in Getränkefabriken
7. g) Leitungen für Bier und dessen Komponenten in Brauereien
8. h) Ölleitungen, Benzinleitungen, Leitungen für Kerosin und andere Treibstoffe
9. i) Rohrleitungen für chemische Flüssigkeiten und Gase in Chemiefabriken
10. j) Teile von öffentlichen Wasserleitungsystemen und Abwasserkanälen mithilfe von Seitenkanalverdichtern

As far as the transported substrates are concerned, the invention can also be used in particular for the following types of lines:

1. a) fresh water pipes
2. b) sewers including pipelines ( 1 ) in sewage treatment plants
3. c) gas pipes
4. d) Heating pipes, especially for underfloor heating
5. e) Absorber pipes and pipes for the transmission of the heat transfer medium (liquid or gaseous) for solar thermal systems
6. f) piping for drinks and their components in beverage factories
7. g) Lines for beer and its components in breweries
8. h) Oil pipes, fuel lines, kerosene pipes and other fuels
9. i) Pipelines for chemical liquids and gases in chemical plants
10. j) Parts of public water systems and sewers using side channel compressors

embodiments

Embodiment of Figure 1 - Simple vacuum test with electric vacuum pump

In this embodiment, the electric vacuum pump ( 8th ) via a fluid line ( 6 ) directly at the fluid connection of the pipeline system ( 2 ) connected. The compressor air tank ( 23 ) also via a fluid line ( 6 ) connected vibrator ( 24 ) is used to transmit the vibration directly to the piping system ( 1 ) attached.

Here, the electric vacuum pump ( 8th ) exclusively for generating an overpressure in the pipeline system ( 1 ) while the compressor ( 22 ) only serves to generate the vibration. The generation of the negative pressure by the electric vacuum pump ( 8th ) can therefore even if only one compressor ( 22 ), simultaneously with the generation of the vibration by the compressor ( 22 ) occur. Of course, both functions can also be exercised separately at any different times.

Exemplary embodiment according to FIG. 2 - Simple vacuum test with Venturi nozzle

In the embodiment according to 2 is the venturi nozzle ( 7 ) at the fluid connection of the pipeline system ( 2 ). A fluid line ( 6 ) connects the compressor air tank ( 23 ) either with the Venturi nozzle ( 7 ) or with the vibrator ( 24 ), so that in the presence of only one compressor ( 22 ) only one process can take place, either the generation of the negative pressure or the vibration. Performing both operations simultaneously would be possible, for example, with additional installation of a check valve ( 25 ), as in the embodiment and 5 for negative pressure and overpressure and in the embodiment according to 3 is intended for overpressure.

Embodiment of Figure 3 - Simple overpressure test with compressor

In a simple way you can do a positive pressure test with vibration after the in 3 perform illustrated embodiment.

For this purpose, to increase the air pressure in the piping system ( 1 ) to the fluid port of the pipeline system ( 2 ) by means of a fluid line ( 6 ) the compressor air tank ( 23 ) connected. By switching on the compressor ( 22 ) and generation of the desired pressure in the compressor compressed air tank ( 23 ), the corresponding overpressure in the piping system ( 1 ) be achieved.

Alternatively, the equipment yields 3 the possibility of using a fluid line ( 6 ) instead of the piping system ( 1 ) a vibrator ( 24 ) to the compressor air tank ( 23 ) of the compressor ( 22 ). For this purpose, the connection of the pipeline system ( 1 ) and the vibrator ( 24 ) to the compressor air tank ( 23 ) as the alternatively connectable fluid port ( 29 ) in 5 shown. The compressor compressed air tank ( 23 ) can therefore be used alternately to create a vacuum in the piping system ( 1 ) or the vibrator ( 24 ) to the pipeline system ( 1 ). For this purpose, the vibrator is connected to a pipe section of the pipeline system ( 1 ) so that its vibrations on the piping system ( 1 ) transfer.

In doing so, the vibration during the piping system ( 1 ) to apply existing overpressure is the check valve ( 25 ) provided after the increase in pressure in the piping system ( 1 ) ensures that the alternatively connectable fluid port ( 29 ) from the fluid connection of the pipeline system ( 2 ) and to the vibrator ( 24 ) can be connected without the pressure from the piping system ( 1 ) escapes. This allows the vibration then in the previously generated overpressure in the piping system ( 1 ).

In order to avoid having to switch over between the production of overpressure in the piping system ( 1 ) and the vibration of the compressor air tank ( 23 ) connected alternatively connectable fluid port ( 29 ) repeatedly between the vibrator ( 24 ) and the piping system ( 1 ), the alternatively connectable fluid connection ( 29 ) replaced by a 3/2-way valve, that is, by a valve with 3 Connections and 2 possible switching positions, through which this switching can be made with a handle.

Exemplary embodiment according to FIG. 5 - Circuit diagram overpressure and negative pressure combined

1. (1) die Vibrations-Prüfung mit Überdruck nach 5,
2. (2) die Vibrations-Prüfung mit Unterdruck nach 5,
3. (3) die Vibrations-Prüfung unter Verwendung beider Druckvarianten nach 5.

The embodiment according to 4 and 5 offers - supported by the test system ( 3 ) - using a vibrator ( 24 ) - which is provided in this example as a compressed air vibrator (eg ball vibrator, roller vibrator, piston vibrator) - three ways to leak test a piping system ( 1 ), namely

1. (1) the vibration test with overpressure after 5 .
2. (2) the vacuum vibration test after 5 .
3. (3) the vibration test using both pressure variants 5 ,

To switch between the overpressure vibration test and the negative pressure vibration test, you can 5 the alternatively connectable fluid port ( 29 ) the piping system ( 1 ) optionally in two ways with the test system ( 3 ), either with the positive pressure connection on the pipeline system test system ( 12 ) or with the vacuum connection on the test system for the piping system ( 11 ).

Partial example: Vibration test with overpressure according to FIG. 5

To the leak test method by vibration according to 4 and 5 in connection with overpressure according to 4 and 5 The technical equipment listed there for the vacuum test must be present and connected as shown:

The test system ( 3 ), which is shown by a dashed line, summarizes the essential equipment required for the control of the leak test and connections, such as 4 and 5 demonstrate.

The control elements of the vibrator ( 24 ) are on the left side of the test system ( 3 ). At the top left is the fluid port on the compressor air tank test system ( 4 ) connected to the externally housed compressor air tank ( 23 ) of the compressor ( 22 ) through a fluid line ( 6 ) is connected. To the right of the fluid port on the compressor air tank test system ( 4 ) is the compressed air connection for the vibrator ( 5 ). Between these two connections is a fluid line ( 6 ), along which various devices are installed from the left port toward the right port as follows:

From the fluid port on the compressor air tank test system ( 4 ) within the test system ( 3 ) a fluid line ( 6 ) first to the pressure regulator for the vibrator ( 17 ), with which the working pressure for the air-driven vibrators ( 24 ) (eg ball, roller or piston vibrators) and thus can adjust their vibration frequency. From here, the compressed air line continues to the on-off switch for the vibrator ( 19 ), with which the vibrators ( 24 ) can be switched on and off. From this switch one leads the fluid line ( 6 ) to the manometer for the vibrator working pressure ( 13 ), which is used to check the pressure set for the vibrator and relevant to the vibration frequency. From here, the fluid line ( 6 ) to the compressed air connection for the vibrator ( 5 ), where the vibrators ( 24 ) are to be connected. These are connected to the pipes of the pipeline system to be tested ( 1 ), eg with pipe clamps, screw clamps or rubber bands so that they can transmit their vibration to these lines after they are switched on.

To check the pressure in the compressor air tank ( 23 ) of the test system ( 3 ) is at the fluid line ( 6 ) between the fluid port on the compressor air tank test system ( 4 ) and the pressure regulator for the vibrator ( 17 ) a pressure gauge for the compressor tank ( 16 ) connected.

To perform the pressure test using excess pressure, the test system ( 3 ) are installed and connected to each other by a compressed air line:

From the fluid line ( 6 ) between the fluid port on the compressor air tank test system ( 4 ) and the pressure regulator for the vibrator ( 17 ) is branched off a compressed air line to which a pressure regulator for the pipeline system ( 18 ), with the help of which one for the further course of this line for the piping system ( 1 ) can set the maximum required pressure. This also serves to avoid the inadvertent setting of too high a pressure during the pressure test of the pipeline system ( 1 ) by the regulator for overpressure in the pipeline system ( 21 ).

Next, the device is connected to the controller for overpressure in the piping system ( 21 ) via another piece of fluid line ( 6 ) a pressure gauge for the pipeline system ( 15 ), with the help of which the air pressure in the piping system ( 1 ) can be read. Between this gauge pressure gauge for the piping system ( 15 ) and the overpressure connection on the test system for the pipeline system ( 12 ), a check valve ( 25 ), which ensures that the piping system ( 1 ) located pressure does not escape unintentionally.

With the overpressure connection on the test system for the piping system ( 12 ), the alternatively connectable fluid port ( 29 ) the piping system ( 1 ) via a fluid line ( 6 ), with an intermediate filter ( 26 ) prevents that in the piping system ( 1 ) contaminants - in particular by the vibrators ( 24 ) dissolved particles - when draining the overpressure from the piping system ( 1 ) pollute the test equipment. You can also use the filter ( 26 ) from the piping system ( 1 ) particles are collected for a possible later assessment.

1. a) Überdruck Verstärken
2. b) Stopp
3. c) Überdruck Verringern

Now, for the implementation of the leak test method by vibration and overpressure all devices as in 5 represented with each other and with the piping system ( 1 ) are associated with the special feature that the alternatively connectable fluid connection ( 29 ) at the vacuum connection on the test system for the piping system ( 11 ), after switching on the compressor ( 22 ) the air in the compressor air tank ( 23 ), the pre-pressure through the inlet pressure regulator for the pipeline system ( 18 ) and controlled by the regulator for overpressure in the piping system ( 21 ) of the respective desired pressure can be set. This regulator for overpressure in the piping system ( 21 ) has three switching options for this purpose:

1. a) increase overpressure
2. b) Stop
3. c) Reduce Overpressure

In addition, with the on-off switch for the vibrator ( 19 ) the vibrators ( 24 ) are actuated before, during or after the described generation of the overpressure in order to remove particles from leaks in the pipeline system ( 1 ) to solve. This can be done by changing the vibrator working pressure through the pressure regulator for the vibrator ( 17 ) the vibrators ( 24 ) are operated with different air pressure and thus with different vibration frequencies.

It is also possible, the pressure in the piping system ( 1 ) repeatedly and to release again, or to produce the overpressure before the vibration and only after the completion of the vibration to release the excess pressure again. You can use the vibrators ( 24 ), in each case before, during or after the pressure build-up with different vibration frequencies, which can be helpful because it is not always possible to accurately predict which vibration frequency for the size and the material of the pipes of the pipeline system ( 1 ) is most suitable - the most favorable frequency also depends on the type and size of the particles clogging the leaks.

Partial example: Vibration test with negative pressure according to FIG. 5

For the application of vibration according to 4 and 5 in the context of negative pressure are other devices in the test system ( 3 ) to install. The venturi nozzle to be operated by means of compressed air for generating negative pressure ( 7 ), in addition to the test system ( 3 ) is accommodated in a separate area, receives the pressure required to generate the negative pressure from the compressor compressed air tank ( 23 ). The Venturi nozzle ( 7 ) is therefore via a fluid line ( 6 ) at the fluid port on the compressor air tank test system ( 4 ) connected. Your vacuum connection is via a fluid line ( 6 ) with the regulator for underpressure in the piping system ( 20 ), from where the alternatively connectable fluid port ( 29 ) via a filter ( 26 ) and via a fluid line ( 6 ) to the vacuum connection on the test system for the pipeline system ( 11 ) leads. Here, the filter ( 26 ) sure that the piping system ( 1 ) contaminants - in particular by the vibrators ( 24 ) dissolved particles - in the generation of the negative pressure from the piping system ( 1 ) do not pollute the test equipment and are also collected for possible subsequent assessment of the particles. The check valve ( 25 ) also ensures that the piping system ( 1 ) is not unintentionally lost.

1. a) Vakuum verstärken = Druck verringern
2. b) Stopp
3. c) Vakuum abschwächen = Druck erhöhen

This regulator for negative pressure in the piping system ( 20 ) has three switching options for the purpose of vacuum control:

1. a) Increase vacuum = reduce pressure
2. b) Stop
3. c) Reduce vacuum = increase pressure

To carry out the vibration test method with negative pressure according to 5 all devices will be like in 5 represented with each other and with the piping system ( 1 ), with the special feature that the alternatively connectable fluid connection ( 29 ) at the overpressure connection on the test system for the pipeline system ( 12 ) is to be connected. The further from the filter ( 26 ) coming hose connection is connected to the fluid connection of the piping system ( 2 ) connected. The compressor compressed air tank ( 23 ) is via a fluid line ( 6 ) with the fluid port on the compressor air tank test system ( 4 ) connect to. All other connections will be made according to 5 performed.

Changing use of both printing methods according to FIG. 5

The following two embodiments according to 5 for the method of testing the tightness of piping systems ( 1 ) provide a switch between the overpressure vibration test and the negative pressure vibration test. On the one hand, the alternatively connectable fluid connection ( 29 ), but in its place also a directional control valve are used for this change.

Alternatively connectable pneumatic connection

In order to switch between the overpressure vibration test and the negative pressure vibration test, it is possible, as stated above 5 the alternatively connectable fluid port ( 29 ) the piping system ( 1 ) optionally in two ways with the test system ( 3 ), either with the positive pressure connection on the pipeline system test system ( 12 ) or with the vacuum connection on the test system for the piping system ( 11 ).

Directional valve instead of alternative connection

To the embodiment according to 5 to avoid repeated switching between the generation of overpressure and the generation of negative pressure in the piping system ( 1 ) of the pipeline system ( 1 ) coming alternative connectable fluid port ( 29 ) repeatedly between the vacuum connection on the test system for the piping system ( 11 ) and the overpressure connection on the test system for the pipeline system ( 12 ), it is possible to replace the alternatively connectable compressed air connection ( 29 ) use a directional control valve - eg a 3/2-way valve with three connections and two possible switching positions - through which this changeover can be carried out with a handle.

It can be used to switch between the tightness test with overpressure and the tightness test with negative pressure a directional control valve, which can be adjusted on the one hand so that the piping system ( 1 ) for the overpressure test with the overpressure connection on the test system for the pipeline system ( 12 ) and from the vacuum connection on the pipeline system test system ( 11 ), but which can also be adjusted so that the piping system ( 1 ) for the vacuum test with the vacuum connection on the pipeline system test system ( 11 ) and from the overpressure port on the piping system test system ( 12 ) is separated.

Exemplary embodiments: Various pneumatic vibrators

1. (1) Kugelvibrator für kleinere bzw. leichtere Rohrtypen
2. (2) Rollenvibrator für etwas größere bzw. schwerere Rohrtypen
3. (3) Kolbenvibrator für sehr große bzw. sehr schwere Rohrtypen

In the application of the method, different pneumatic vibrators are preferably used for different sized or different heavy tube types, eg:

1. (1) Ball vibrator for smaller or lighter tube types
2. (2) Roller vibrator for slightly larger or heavier pipe types
3. (3) Piston vibrator for very large or very heavy pipe types

Exemplary embodiment: Venturi nozzle

To generate the negative pressure can also be a Venturi nozzle ( 7 ) deploy. It is powered by a compressor ( 22 ) operated by compressed air. The flow of compressed air through the nozzle generated at the on Piping system ( 1 ) connected to the Venturi nozzle ( 7 ) for the pipeline system ( 1 ) desired negative pressure. The advantage of the Venturi nozzle ( 7 ) is in her low price.

Filter between pipeline and compressor or Venturi nozzle

Another embodiment is a filter which is mounted between the pipeline and the compressor or venturi.

In the compressed air tightness test, using a filter ( 26 ) between the piping system ( 1 ) and the compressor air tank ( 23 ), prevents that in the piping system ( 1 ) contaminants - in particular by the vibrators ( 24 ) dissolved particles - when draining the overpressure from the piping system ( 1 ) pollute the test equipment.

In the vacuum process, the filter begins ( 26 ) the pollutants and particles during the generation of negative pressure.

The collection of particles and contaminants in the filter ( 26 ) makes it possible to investigate them, eg to find out the causes of the pollution.

Embodiment: Side channel compressor

A side channel blower, which has much more power than the previously described overpressure or vacuum generator, can be used to generate overpressure and underpressure in the piping system ( 1 ) of larger dimensions, for more stable, large diameter tubes, such as those found in large industrial plants.

The use in sections of a public water or sewage system is possible.

Exemplary embodiment: Measuring device for external pressure

In the event that the piping system ( 1 ) surrounding pressure is not identical to the atmospheric pressure, there is the possibility for all of the embodiments and embodiments listed here, to add another overpressure or vacuum gauge for determining and recording the piping system ( 1 ) surrounding external pressure.

Embodiment: Differential measuring device

It is also conceivable to connect a differential pressure measuring device to the pipeline system ( 1 ) and the surrounding space, by which the difference between the pipeline system ( 1 ) surrounding external pressure and the internal pressure in the pipeline system ( 1 ) is determined.

list of figures

• 1 - Simple vacuum test with electric vacuum pump
• 2 - Simple vacuum test with Venturi nozzle
• 3 - Simple overpressure test with compressor
• 4 - Control panel overpressure and vacuum combined
• 5 - Wiring diagram overpressure and negative pressure combined

LIST OF REFERENCE NUMBERS

- Piping system and connections - (1) Piping (2) Fluid connection of the piping system - Instruments and connections on the control panel - (3) Test System (4) Fluid connection on the test system for the compressor compressed air tank (5) Compressed air connection for the vibrator (6) Fluid conduit (7) Venturi nozzle (8th) electric vacuum pump (9) Fluid connection on the test system for external vacuum gauge (10) Fluid connection on the test system for external overpressure measuring device (11) Vacuum connection on the test system for the piping system (12) Overpressure connection on the test system for the piping system (13) Pressure gauge for vibrator working pressure (14) Vacuum pressure gauge for the piping system (15) Overpressure pressure gauge for the piping system (16) Pressure gauge for the compressor tank (17) Pressure regulator for the vibrator (18) Prior pressure regulator for the piping system (19) On-off switch for the vibrator - adjustable: a) Off b) One (20) Regulator for negative pressure in the piping system - adjustable: a) increase overpressure b) Stop c) Reduce Overpressure (21) Regulator for overpressure in the piping system - adjustable: a) Increase vacuum = reduce pressure b) Stop c) Reduce vacuum = increase pressure - Instruments and connections outside the control panel - (22) compressor (23) Compressor compressed air tank (24) vibrator (25) check valve (26) filter (27) external vacuum gauge (28) external overpressure measuring device (29) alternatively connectable fluid port

Claims (10)

Method for checking the tightness of piping systems (1), based on an examination of the resistance of the internal pressure prevailing inside the piping system (1) to a different external pressure surrounding the piping system (1), characterized in that the possibility of Misslingens the tightness test due to a clogging of leaks in the conduit system is reduced by vibrations transmitted by at least one vibrator (24) at least one point of the piping system (1). Method according to Claim 1 , characterized in that it is the internal pressure differing from the external pressure is an increased relative to the external pressure inner pressure. Method according to Claim 1 , characterized in that it is the internal pressure differing from the external pressure is a relation to the external pressure reduced internal pressure. Method according to at least one of Claims 1 . 2 . 3 , characterized in that during the vibration takes place at least one pressure change in the piping system (1). Method according to at least one of Claims 1 . 2 . 3 . 4 , characterized in that a check valve (25) is provided between the conduit system and the device which is usable for generating the pressure difference. Method according to at least one of Claims 1 . 3 . 4 . 5 , characterized in that the generation of negative pressure by means of a Venturi nozzle (7). Method according to at least one of Claims 1 . 3 . 4 . 5 . 6 , characterized in that the generation of negative pressure by an electric vacuum pump (8). Method according to at least one of Claims 1 . 2 . 3 . 4 . 5 . 6 . 7 , characterized in that the vibrator (24) by means of an elastic band to a pipe of the piping system (1) is attached. Method according to at least one of Claims 1 . 2 . 3 . 4 . 5 . 6 . 7 . 8th , characterized in that the pressure changes occurring during the leak test in the pipeline system (1) are determined and recorded by means of a measuring device. Arrangement for carrying out a leak test on a pipeline system (1) based on an examination of the resistance of the internal pressure prevailing inside the pipeline system (1) to a different external pressure surrounding the pipeline system (1), comprising a device for effecting a pressure change ((7), (8), (22)), connectable to the piping system (1) via a fluid connection, b) a manometer ((14), (15), (16)) for measuring the in the piping system (1 ) existing internal pressure, characterized in that the possibility of failure of the leak test due to a clogging of leaks in the conduit system is reduced by the fact that by operating a likewise contained in the arrangement on the piping system (1) vibrator (24) vibrations on the piping system (1) be transferred.

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